DE2837638A1 - FOR THE FRAGMENT OF PRE-TREATED BATTLEHEAD AND THE PROCESS FOR ITS MANUFACTURING - Google Patents

Description

GLAWE ₁ DELFS, MOLL & PARTNHR

Aktiebolaget Bofors

690 20 Bofors / Sweden

"For fragmentation pre-treated warhead as well as process too its manufacture "

PATENT LAWYERS

DR.-ING. RICHARD GLAWE, MONKS DIPL.-ING. KLAUS DELFS, HAMBURG DIPL.-PHYS. DR. WALTER MOLL, MÖNCHEN DIPL.-CHEM. DR. ULRICH MENGDEHL, HAMBURG

8000 MÖNCHEN 26 POST BOX 37 LIEBHERRSTR. 20 TEL. (089) 22 65 48 TELEX 5225 05

MUNICH A 31

2000 HAMBURG POST BOX 2570 ROTHENBAUM-CHAUSSEE SB TEL. (040) 41020 TELEX 212921

Description

The invention relates to a steel warhead, which is intended for splintering and is pretreated. The invention also relates to a method for producing the warhead in question.

5 The term "warhead" in this context means primarily the fragmentation body of various types of ammunition meant, such as projectiles, missiles, torpedoes, mines, etc., where it is often desirable that the fragmentation body Shards of a predetermined size and / or shape should be able to deliver 10.

For this purpose the fragment body in question was used with

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mechanical predetermined breaking points in the form of impressions provided, or a suitable steel material has been selected which has been subjected to a heat treatment in order to prepare for the fragmentation. In the known methods, however, there is a limited choice both regarding the steel material as well as the manufacturing process o In this context should only be mentioned that cold flow is not possible with the previously known processes.

The main object of the invention is to provide an apparatus and a method with which the above mentioned problems can be solved.

The feature which can mainly be considered characteristic of the invention ₉ is that narrow martensitic zones are created in the warhead, along which the warhead breaks when it is made to shatter. The manufacturing process for such a warhead, in order to prepare the same sum fragmentation, consists essentially in that narrow martensitic zones are created in the material of the warhead.

The warhead is preferably made from a tough steel material. Ba the martensite phase extremely is brittle, it will break in front of the main material of the warhead if it is damaged by the explosive charge »

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that is used is fragmented. Because the martensite phase is extremely brittle, a crack can form and propagate before cracks occur in the other warhead material. The radius of the point at which the jump occurs can be kept very small, and the stresses in the material around the crack are relatively high and jumps will occur in a controlled manner.

The invention is based on advantageous in the following Embodiments described for example with reference to the accompanying drawing, in side view a projectile is shown which is provided with martensite zones by means of a heat source.

In the figure, a projectile is denoted by 1 and a heat source in the form of a laser is denoted by 2. The projectile can from be one of the conventional types that have a fragmentation body and an explosive charge that detonates when detonated breaks open the splinter body. The laser emits a laser beam 3, which through a reflector 4 on the Outer surface of the projectile is passed, which forms the fragment body, which are fragmented according to the invention target.

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The reflector 4 is of a type known per se, which is so arranged with the aid of devices not shown is that it can be rotated around point 5. The facilities can also be known per se Way to be arranged so that rotational movements of the reflector not only in the plane of the figure in the through the arrows 6 indicated directions, but also in one or more directions with respect to this plane can take place. The projectile is arranged so that it can be rotated about its axis by means of devices that are not shown. The rotation of the projectile can be in the direction of arrow 8, in the opposite direction Direction or in both directions.

By such an arrangement can be achieved that the laser beam the rotary movements of the reflector 4 and the rotational movement of the projectile 1 can follow and / or on the surface of the projectile depending on the Heat source can be brought into contact with the tracks or zones 9 or removed from them. the Zones can be formed so that they are contiguous with one another or that they are divided into zones, the are separated from each other, so that the desired geometries of the structure are obtained. The Martensite zones are included made as deep as possible like this with this one

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Procedure is possible.

Zone 9 can be viewed as consisting of a number of points, one of which is in the figure is denoted by the reference numeral 10. The laser beam heats the material locally at this point a temperature which corresponds to the martensite temperature for the selected steel material. When the beam goes to the next point of the zone in question is moved, the material cools in the previously heated point or zone rapidly, due to the fact that the area of the point or zone is relatively small is so that the material surrounding the point or zone in the fragment body can absorb the heat from the point or zone very quickly. It becomes through it get a rapid hardening, which leads to the result that the martensite phase is established, which then remains. Because martensite has a lower density than the base material has, iijker surface compressive stresses are generated, which are highly static fractures counteract.

By using a laser as a heat source, you can with the arrangement shown, in principle, the pattern formed can be selected as desired. In addition, the procedure run in air. However, it is also possible

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lent the martensitic zones with the help of an electron beam to generate, in which case the method is preferably carried out in a vacuum, so that a sufficient! more coherent Electron beam is obtained to form a narrow zone.

In one embodiment of the method according to the invention the map site phase is generated in the respective point of the zone by the fact that the material in the point the temperature in question is heated with the help of a heat source or a reflector moving along the zones and that upon movement of the heat source away from the point, rapid heat dissipation cures takes place in the material surrounding the point.

In the figure, reference numeral 11 denotes a space in which the martensitic zones are generated. It is assumed that this space is under vacuum when the heat source is an electron beam.

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Claims (5)

GLAWE, DELFS, MOLL & PARTNER PATENT LAWYERS DR-IKQ. RICHAHQ GLAWE, MONKS BIPL - ING. KLAUS DELFS. HAMBURG DIPL.-PKVS. DEL WALTER MOLL, MONKS DiPL-CHEM. DR. ULRICH MENJDEHL. HAMBURS 80QO MOKCHEN 26 2000 HAMBURG 13 PO Box 37 PO Box 2570 Aktr.ebolaget Bofors uebherrstr. _20th 20 Bofors / Sweden th_ m 225543 TELEK522505 - TELEX212921 "For fragmentation pre-treated warhead as well as process
for its production "MÖNCHEN A 31 Claims Steel warhead with pre-treatment for lightening the fragmentation of the warhead, characterized in that narrow Martensite zones (9) are formed in the warhead, along which the warhead breaks when made to shatter. 2. Manufacturing method for a warhead made of steel according to claim 1, characterized in that that narrow martensitic zones (9) are formed in the material of the warhead. - 1 909810/0928 BANK: DRESDNER BANK, HAMBURG. 4 030 448 (sort code 200800 00). POST CHECK: HAMBURG 147607-200 TELEGRAM: SPECHTZIES 3. The method according to claim 2, characterized in that the martensite phase in points the zones (9) by heating the material in point (10) to the temperature required for this by means of a heat source (2) or a reflector (4) is generated which can be aligned along the zones (9), and that curing takes place after the heat source is moved away from point (10), in_dem rapid heat dissipation takes place in the material surrounding the point (10) in the warhead (1). 4. The method according to claim 2 or 3, characterized in that a heat source (2), the a laser beam (3) or an electron beam generated, is moved along the zones (9) so that a predetermined geometric pattern is obtained. 5. The method according to claim 4, characterized in that when using a heat source (2) with a laser beam (3) of the warhead (1) is rotated with respect to a rotatable reflector (4), which the Laser beam (3) reflected. 909810/0926