ES2425929T3 - Kinetic Energy Penetrator - Google Patents

Abstract

The penetrator (1) has a cylindrical penetration body (2) containing an explosive charge (3) initiated by a priming unit i.e. rocket engine (4), where length (L) of the penetrator is less than or equal to 500 mm. The penetration body is extended by a warhead (5) made of tungsten based material having high mechanical characteristics, where thickness (E) of the penetration body increases progressively and continuously at the level of connection of the penetration body with the warhead. The penetration body and the warhead are formed as a single piece.

Description

[0001] The technical field of the invention relates to kinetic energy penetrators intended to be dispersed by a carrier such as a missile to destroy concrete and steel reinforced targets.

[0002] The existence of cruise missiles capable of destroying important concrete thicknesses (close to one meter) is known. However, these missiles have a considerable mass (greater than 500 Kg. Even close to 1000 Kg.) And are very expensive to apply. These do not adapt to more modest concreted whites that have a thickness of a few tens of centimeters.

[0003] It is necessary with these targets to use the artillery shots that most of the time need the firing of several shells and do not have the desired precision to perform "high precision attacks"; In an urban context.

[0004] It would be appropriate to provide lighter guided munitions (mass of the order of 20 to 50 kg), such as air / ground or ground / ground missiles, of the ability to drill concrete targets. However, it is thus necessary to reduce the mass of the perforator to less than 10 kilograms, which greatly impairs its efficiency and on the other hand the speed transmitted by the missile to this perforator remains moderate (less than 300 meters per second).

[0005] In addition, most of the time it is necessary to carry out ammunition that has a certain lethal radius, that is, to generate fragments during the initiation of the explosive. This imposes being able to place a mass of explosive quite important in the perforator to transmit an effective speed to the fragments (this again reduces the mass attributed to the piercing body, hence its effectiveness).

[0006] Different concepts have been proposed to perform this penetrator.

[0007] Patent EP965028 thus proposes to arrange a ballast in tungsten alloy inside a steel shell. This solution effectively increases the mass-diameter ratio of the penetrator, which is favorable to drilling.

[0008] However, the mechanical characteristics of the tungsten alloy that is applied do not adapt to penetration, which limits the penetrating capacity of this penetrator.

[0009] It is also known from the patent EP1701131 a penetrator that associates a large diameter steel body and a small diameter front insert made of tungsten alloy with high mechanical characteristics and that is housed in a front body piercing.

[0010] This penetrator is nevertheless conceived to have an important diameter and mass (perforating pump body, diameter of about 90mm). Although it includes a perforated tip of tungsten of reduced caliber (40mm) in its front part, the mechanical characteristics of the body surrounding this tungsten tip are not sufficient to participate effectively in the perforation.

[0011] The object of the invention is to propose a penetrator that allows to overcome such inconveniences.

[0012] The penetrator according to the invention has important perforating capacities despite a moderate speed and reduced dimensions. This penetrator is however capable of producing fragments after crossing the target.

[0013] So that the invention has as its object a kinetic energy penetrator comprising a piercing body in which an explosive charge is included that can be initiated by a priming means, Penetrator characterized by the fact that the body substantially cylindrical in which the explosive material is included is extended by an ogive made entirely of a tungsten-based material and of great mechanical characteristics.

[0014] According to one characteristic, the thickness of the body increases progressively and continuously at the level of its connection with the warhead.

[0015] According to one embodiment, the cylindrical body can be made in one piece with the ogive.

[0016] According to another embodiment, the warhead can have an axial perforation in which a tip is to be housed. made of a tungsten-based material that has a practical strength of 0.2% elongation (RP0.2) greater than or equal to 1500 megapascals and an elongation greater than 8%. [0017] According to another embodiment, the body is a tubular element sealed in its front part by the ogive.

[0018] The body can be made of steel.

[0020] In this case, the warhead will be made of a tungsten-based material with a practical resistance of 0.2% elongation (RP0.2) greater than or equal to 1500 megapascals and an elongation greater than 8%.

[0021] The body material may have a weakened area that favors fragmentation.

[0022] The penetrator may have a length less than or equal to 500 mm and a diameter less than or equal to 100mm.

[0023] The invention will be better understood in reading the following description of different embodiments, description made in reference to the accompanying drawings in which:

-

 Figure 1 shows in half view, half longitudinal section a penetrator according to a first embodiment of the invention,

-

 Figure 2 shows in half view, half longitudinal section a penetrator according to a second embodiment of the invention,

-

 Figure 3 shows in half view, half longitudinal section a penetrator according to a third embodiment of the invention.

[0024] Referring to Figure 1, a kinetic energy penetrator 1 according to the invention includes a piercing body 2 that delimits an internal cavity 2a in which an explosive charge 3 is included which can be initiated by a priming means 4 (or rocket). The rocket 4 is to be designed, for example, to ensure the initiation of the explosive charge 3 only after a certain delay after the impact on a target. Safely, only explosive charge 3 will be initiated once the target is crossed.

[0025] The body 2 is substantially cylindrical and is extended by an ogive 5 made entirely of a tungsten-based material with great mechanical characteristics.

[0026] According to the embodiment shown in Figure 1, the cylindrical body 2 is made in one piece with the ogive 5.

[0027] A tungsten-based material (higher density) will be chosen as common material for body 2 and warhead 5

or equal to 17) and high mechanical characteristics. High mechanical characteristics are understood as a material whose practical resistance to 0.2% elongation (RP0.2) is greater than or equal to 1000 megapascals. These tungsten alloys are those that are normally used to make the bars of arrows ammunition fired by the tank cannons. FR2622209 describes an example of such material.

[0028] The ogival body 2 will be obtained for example by sintering. In addition, the thickness E of the body 2 is chosen sufficiently weak so that the capacity of the explosive 3 is maximum and that the efficiency of the fragments is ensured at the time of the initiation of the charge 3. For a tungsten body of high mechanical characteristics , a wall of body 2 with a thickness E of 3 to 5 millimeters can be made.

[0029] To control the size of the fragments generated, a weakened area that favors fragmentation can be provided outside the body 2. As an example, a weakened area 6 formed by a network of lines 6a, 6b that delimits the desired fragments has been shown in the lower half view of FIG. This weakened area can be done by laser, by electronic bombardment or by machining.

[0030] It is seen in Figure 1 that the warhead 5 is continuously connected with the cylindrical body 2. There is no discontinuity at the level of the external connection profile. In addition, it can also be distinguished that the explosive material 3 includes a front part 3a, of length A and of progressively decreasing diameter, front part that penetrates at the level of the back of the warhead 5.

[0031] Thus, the thickness E of the body 2 grows progressively and continuously over the entire length A. The result is an improved mechanical resistance during the impact of the body 2 on a target. The ogive 5 is not separated from the body 2 despite the fact that the thickness E of the latter is minimized to ensure the formation of the desired fragments.

[0032] The massive part of the ogive 5 extends over a length B. A body 2 will be defined such that the massive length B is between 20% and 35% of the total length L of the body 2. This ensures a length LA of the fragment generating part that allows a satisfactory amount of fragments to be obtained.

[0033] Such a definition ensures the best compromise at body level 2 between its piercing efficacy and its effectiveness as a fragment generator.

[0034] It can be seen that tungsten alloys have a density equivalent to substantially twice the density of steel. The volume of body material itself can thus be divided between two for a comparable penetrator mass, which allows for a higher explosive capacity and provides an important body length with effective fragmentation (length L-A-B). The length L-A-B can thus represent about 70% of the total length L.

[0035] For comparison, an identical mass penetrator with a steel body and in which only the ogive 5 is made of tungsten alloy will have a fragmentary useful length that will not exceed 40% of the total length.

[0036] The density of tungsten allows to obtain the fragments that, for a given mass, are twice smaller than the steel fragments. This results in a decrease in the aerodynamic resistance of the fragments and consequently an increase in their long-range impact speed. The drilling capabilities of the fragments also increase due to their higher density. The fragments are therefore much more effective, especially in long range. Finally, with a similar fragment mass, as the dimensions of the tungsten fragments are smaller, there will be more fragments in the same penetrator length.

[0037] Thanks to the invention, a penetrator with a diameter of less than 90mm and a length of less than 500mm can be made.

[0038] Figure 2 shows a second embodiment that differs from the previous one in that the body 2 is a tubular element sealed in its front part by the ogive 5.

[0039] Therefore, two distinct pieces are distinguished here that are connected to each other by means of solidarity such as a thread or radial pins (not shown).

[0040] The ogive 5 includes a thinner rear part 5a which is positioned on a cylindrical seat 2b of the front part of the cylindrical body 2. The body 2 is also arranged in abutment against a projection 5b of the ogive 5, while the back of the ogive is in stop against a housing 2c of the body 2. These machining is carried out in such a way that there is no roughness or geometric discontinuities of the penetrator profile during the passage of the ogive 5 to the cylindrical body 2, and this both at the level of the external profile and the internal profile received by the explosive 3.

[0041] It can also be seen that, as in the preceding embodiment, the explosive material 3 includes a front part 3a, of length A and of progressively decreasing diameter, which penetrates at the level of the back of the warhead 5.

[0042] In this way the thickness E of the body 2 which includes the warhead 5 increases progressively and continuously throughout the entire length A. Again, the result of the foregoing is defined by an improved mechanical resistance during the impact of the body 2 on a white

[0043] Body 2 will also be made of a tungsten-based material. However, the material of the body 2 may be provided with mechanical characteristics inferior to those of the material of the warhead 5.

[0044] For example, a perforating warhead made of a tungsten-based material with a practical strength of 0.2% elongation (RP0.2) greater than or equal to 1500 megapascals and an elongation greater than 8% may be associated and a body 2 made of a tungsten-based material with a practical resistance of 0.2% between 700 and 900 megapascals and an elongation greater than 20%.

[0045] The material of the ogive 5 is a material applied to the kinetic penetrants (arrow ammunition for tank cannon). Such material is described for example in patent EP313484. Such mechanical characteristics are usually obtained by the application, after the sintering stages, of a slab (or hardening), EP313484 describes this manufacturing process in detail. [0046] The material of body 2 is a sintered and non-forged tungsten alloy. EP349446 describes in its preamble a method of realizing such material.

[0047] This embodiment allows to optimize the material of the body 2 for the formation of fragments while optimizing the material of the ogive 5 for the perforation.

[0048] As in the preceding embodiment, the external surface of the body 2 may include weakened areas 6.

[0049] According to a variant embodiment (not shown), a cylindrical body 2 of steel and a tungsten warhead 5 of high mechanical characteristics (RP0.2 greater than or equal to 1000 or preferably a material having an RP0 may be associated , 2 greater than or equal to 1500 megapascals with an elongation greater than 8%).

[0050] Such a variant allows reducing the cost of the penetrator 1 but the latter will then have a lower efficiency.

[0051] Figure 3 shows a variant embodiment in which the body 2 includes as in the embodiment of

5 Figure 1, a front ogive 5 made of the same material as the body 2. However, this differs in this way from the fact that the ogive 5 includes an axial perforation 8 in which a front tip 7 fixed by means of threaded or glued. The front part of the ogive 5 is in support against a projection 7a of the tip 7. This tip is made of an alloy of high mechanical characteristics that has a practical resistance of 0.2% elongation (RP0.2) greater than or equal to at 1500 megapascals and an elongation greater than 8%. The rest of body 2 is

10 performs in an alloy optimized for fragmentation (RP0.2 between 700 and 900 megapascals and an elongation greater than 20%).

[0052] The tip extends axially to the explosive charge 3. Also here it can be seen that the thickness E of the body 2 increases regularly throughout the length A of the front part 3a of the explosive charge 3.

Claims (9)

 fifteen

one.

Kinetic energy penetrator (1) comprising a piercing body (2) in which an explosive charge (3) enclosed by a priming means (4), penetrator characterized by the fact that the body (2) substantially cylindrical is enclosed in which the explosive material is enclosed, it is extended by an ogive (5) made entirely of a tungsten-based material with high mechanical characteristics, the body (2) being a tubular element sealed at its front by the ogive (5 ).

2.

Kinetic energy penetrator according to claim 1, characterized in that the thickness of the body (2) increases progressively and continuously at the level of its connection with the ogive (5).

3.

Kinetic energy penetrator according to one of claims 1 or 2, characterized in that the cylindrical body (2) is made in a single piece with the ogive (5).

Four.

Kinetic energy penetrator according to claim 3, characterized in that the warhead (5) has an axial perforation (8) in which a tip (7) made of tungsten-based material with a practical resistance of 0 is housed. , 2% elongation (RP0.2) greater than or equal to 1500 megapascals and an elongation greater than 8%.

5.

Kinetic energy penetrator according to claim 1, characterized in that the body (2) is made of steel.

6.

Kinetic energy penetrator according to claim 1, characterized in that the body (2) is made of a tungsten-based material whose mechanical characteristics are inferior to those of the ogive material (5).

7.

Kinetic energy penetrator according to claim 6, characterized in that the warhead (5) is made of a tungsten-based material with a practical resistance of 0.2% elongation (RP0.2) greater than or equal to 1500 megapascals and an elongation greater than 8%.

8.

Kinetic energy penetrator according to one of claims 1 to 7, characterized in that the material of the body (2) includes a weakened area (6) that favors fragmentation.

9.

Kinetic energy penetrator according to one of claims 1 to 8, characterized in that the penetrator (1) has a length less than or equal to 500 mm and a diameter less than or equal to 100 mm.