DE102022003744A1 - Fine-tuning an explosively formed projectile - Google Patents

Abstract

A charge (2) for forming a projectile (4), with an explosive (8) and a projectile coating (22) for forming the projectile (4), contains a mass coating (28) which is arranged on the projectile coating (22) in such a way that at least one projectile section (32a, b) of the projectile coating (22) is influenced in its acceleration compared to an absent mass coating (28) by at least one mass section (34a, b) of the mass coating (28) during the formation of the projectile (4).In a method for producing the charge (2), the explosive (8) is provided and the projectile coating (22) is arranged on it and the mass coating (28) is arranged on the projectile coating (22) in such a way that at least the projectile section (32a, b) of the projectile coating (22) is influenced in its acceleration compared to an absent mass coating (28) by at least one of the mass sections (34a, b) of the mass coating (28) during the formation of the projectile (4). the absent mass occupancy (28).

Description

The invention relates to an explosively formed projectile (EFP, explosively formed projectile, explosively formed or forged penetrator) and a charge for forming the projectile, i.e. a charge that forms the projectile (projectile-forming charge).

Such a projectile and such a charge is made of "Wikipedia, 'Projectile-forming charge', website, https:// de. wikipedia. org/ wiki/ Projectile_forming_charge, accessed on 11.08.2022" known. A projectile-forming charge is a special type of shaped charge used primarily to destroy armor from a greater distance. In contrast to a shaped charge, the projectile-forming charge forms an aerodynamically stable penetrator (projectile) that is able to overcome a greater flight distance and achieve the maximum effect. In an EFP, a projectile is formed in the shape of a bullet that is more comparable to a normal rifle projectile.

With regard to such projectiles, there is a desire to optimize the EFP geometry/performance.

In practice, it is known that this can be done by adapting, among other things, the coating geometry (geometry of the projectile coating / EFP liner: radius of curvature, wall thickness) or the detonation front (explosive: ignition points, explosive, wave guide).

The detonation front in a corresponding charge is usually a spherical wave. A wave guide reshapes the spherical wave, in particular to achieve a flat detonation wave front, for example. In other words, the wave guide causes a delay in the detonation.

The object of the invention is to propose improvements with respect to a projectile-forming charge.

The object is achieved by a charge according to patent claim 1. Preferred or advantageous embodiments of the invention and other categories of invention emerge from the further claims, the following description and the attached figures.

The charge is a charge for forming a projectile, in other words a projectile-forming charge. The charge contains an explosive. The explosive forms a basic body of the charge or is at least part of the basic body in question. The charge contains a projectile coating that is arranged on the explosive and serves to form the projectile. The projectile coating is also called an EFP liner. The projectile is an EFP.

The explosive and the projectile coating are basically designed together to transform the projectile coating into the basic projectile when the explosive is moved in a blasting direction. The blasting direction is the direction in which the projectile coating is mainly accelerated when the explosive is moved. "Basically" is to be understood in such a way that this refers to an imaginary state in which only the explosive and projectile coating, but not the mass coating (see below), are considered. An imaginary "basic" projectile is formed. The mass coating then leads to a real modification compared to the imaginary state without mass coating. In reality, the explosive and projectile coating and mass coating are then designed to form the real projectile (see below).

The projectile coating covers the explosive in particular in the direction of the explosion. The explosive is contained or held in particular in a pot-shaped dam, for example. The dam can also be considered part of the base body. The direction of the explosion is, for example, the direction in which the pot opening is located, as seen from the explosive. The projectile coating covers the explosive in particular at the pot opening. The charge contains in particular a wave guide for the explosive. The wave guide is in particular arranged in the explosive.

The charge contains a mass component. The mass component is arranged on the projectile component in such a way that at least one section (“projectile section”) of the projectile component is influenced in its acceleration by at least one section (“mass section”) of the mass component when the real projectile is formed, compared to an absent mass component. The “absent mass component” therefore refers to the imaginary basic state of the same charge explained above, only without mass component.

The corresponding projectile section of the projectile coating is also called the liner element. The mass coating therefore represents an additional mass for or above a certain liner element, which must be accelerated by the explosive together with the liner element. The influence on the absent mass coating is therefore to be understood as follows: It is considered how the acceleration of the projectile section would behave if the mass section were not present. The influence The solution is that the projectile section is accelerated differently because the mass occupancy or the mass section is actually present. Thus, the real projectile is shaped differently than the imagined basic projectile and will have a real modified final shape that differs from it.

In particular, the mass allocation or the mass section slows down the acceleration of the projectile section compared to the imaginary state and/or accelerates it in a different direction, since the mass of the mass section must also be accelerated along with the projectile section.

The acceleration always refers to the detonative acceleration phase, i.e. when the projectile loading/projectile sections are accelerated during the decomposition of the explosive by its decomposition/the detonation front.

The mass loading or its design makes it possible to produce a projectile with a different shape overall, with an otherwise unchanged charge compared to the situation if the mass loading were not actually present.

In other words, by introducing/varying the mass loading, the invention makes it possible to redesign the design of the projectile or the actual projectile produced compared to the basic/imagined projectile without having to change the other charge, in particular without having to change the projectile loading and/or the explosive.

In a preferred embodiment, the mass allocation is designed in such a way that at least two (different) projectile sections of the projectile allocation are influenced differently in their acceleration compared to an absent mass allocation. In other words - again compared to the imagined situation where there was no mass allocation - a first projectile section is influenced in its acceleration characteristics in a first way by adding the mass allocation. A second projectile section is then influenced differently/differently by the mass allocation compared to the first projectile section, e.g. more strongly or less strongly, i.e. differently in its acceleration characteristics.

For example, one projectile section is actually slowed down in its acceleration by a mass section, but another projectile section is not, because there is simply no mass section provided there. Thus, by introducing/varying the mass allocation, it is possible to change the shape of the projectile when the explosive is deployed, since different parts/elements/parts of the projectile (projectile sections that form these parts of the projectile) are accelerated differently. This leads to a projectile with a different shape overall.

In a preferred embodiment, at least part of the mass allocation is not part of the projectile formed or does not become a component of the projectile. In particular, the entire mass allocation is not/does not become part of the projectile formed. The corresponding mass allocation thus influences the formation of the projectile, but does not itself become a part or component of the projectile. In other words, the mass allocation only influences the manner in which the projectile is formed, but does not itself contribute to it as a component.

In other words, a projectile is created in basically the same way as in the (imagined) situation if no mass were present; only the shape of the projectile is influenced by the mass.

In a preferred embodiment, the mass coating is arranged on or at the side of the projectile coating facing away from the explosive. The side is in particular a flat side, since the projectile coating is generally designed to be flat/layer-like, i.e. with two flat sides. This makes it particularly easy to influence the acceleration of the projectile sections, since the mass sections only need to be "pushed" by the projectile sections. The more mass a mass section has, the more the acceleration of the associated projectile section is influenced/slowed down/deflected.

In a preferred embodiment, the mass coating is a coating of the projectile coating. The projectile coating is therefore applied directly or indirectly (intermediate layer, for example an adhesive layer) to the coating or is arranged accordingly on it. The mass coating can thus be applied to the projectile coating particularly easily, for example by a coating process.

In a preferred embodiment, the mass coverage has areas/mass sections of different mass density transverse to the blasting direction.

“Mass density” refers to how much mass an infinitesimal Area section of projectile occupancy 22 is assigned to mass occupancy 28.

In certain areas, the mass density can also be zero, i.e. there is no mass coverage there. Mass density means: surface sections of the projectile coverage are exposed to different degrees of mass coverage in a direction perpendicular to the direction of the explosion, in particular they are covered. For example, a first section is covered/influenced by a first mass, another section by a different mass. In particular, only part of the projectile coverage is covered by a mass coverage at all, the rest of the projectile coverage is uncovered (there is zero mass density). Differences in mass density can be achieved, for example, by using locally different materials for the mass coverage. For example, different surface densities of the mass coverage arise in the material itself.

In a preferred variant of this embodiment, the mass coating has mass sections with different mass densities in certain or different areas transverse to the direction of explosion because it is designed with different thicknesses - viewed in the direction of explosion. In other words, the mass coating is designed/arranged with different thicknesses/different distributions on or on the projectile coating and consists in particular of a uniform material. A corresponding mass coating is particularly easy to implement.

In a preferred variant of this embodiment, the charge has a central longitudinal axis running in or along the direction of explosion. The mass density of the mass coating is not rotationally symmetrical with respect to the central longitudinal axis. This means that the projectile coating is coated differently by mass coating in the circumferential direction around the central longitudinal axis and its acceleration is thus influenced compared to an absent mass coating. In this way, non-rotationally symmetrical projectiles can also be produced. This makes it possible, for example, to create fin-like features on projectiles in order to increase their flight stability.

In a preferred variant of this embodiment, the mass coverage on different circular segments or circular ring segments has a different mass density with respect to the central longitudinal axis (either between the segments or between the segments and a remaining area of the projectile coverage). For example, certain circular ring or circular segments of the projectile coverage are covered with mass coverage, other areas or circular segments of the projectile coverage are free of mass coverage or covered with a different mass density. In this way, non-rotationally symmetrical structures of the mass coverage can be implemented particularly easily.

In a preferred embodiment, the mass coating is inert. In other words, the mass coating has an intermaterial, i.e. no energetic or non-energetic material, i.e. no explosives, no pyrotechnics, and therefore does not generate any energy when the explosive is converted. Such material is particularly easy to handle when producing the charge, in particular when producing/applying the mass coating.

In a preferred embodiment, the mass covering is or contains a foam and/or a plastic and/or a metal. Such materials are particularly suitable for corresponding mass coverings.

The object of the invention is also achieved by a method according to claim 12. This serves to produce the charge according to the invention. According to the method, the explosive is provided which forms the base body of the charge or at least forms part of it. The projectile coating is arranged on the explosive. The explosive and the projectile coating are basically set up together to transform the projectile coating into the projectile in the direction of explosion when the explosive is converted. The mass coating is arranged on the projectile coating in such a way that at least the section of the projectile coating is influenced in its acceleration by at least the section of the mass coating when the projectile is formed compared to the (imagined) absent mass coating.

The method and at least some of its possible embodiments as well as the respective advantages have already been explained in connection with the charge according to the invention.

In a preferred embodiment, the mass coating is produced using a 3D printing process. This allows for particularly free design options for the mass coating. In particular, the mass coating is printed directly onto the projectile coating, for example directly or by interposing an adhesive, as already described above.

In a preferred embodiment, the mass coating is produced on or on the projectile coating. This means that the mass coating is not produced as a separate component and then applied to the projectile coating, but the production takes place directly on/at the projectile coating, in particular according to the 3D printing process mentioned above. In other words, the projectile coating in particular is coated with the mass coating.

This makes it particularly easy and effective to apply the mass coating to or arrange it on the projectile coating.

In a preferred embodiment, the mass coating is applied to the otherwise fully prepared charge. "Preparing" means that the explosive is handled, in particular it is combined with the projectile coating to form the corresponding part of the charge. The mass coating is only applied later.

This opens up the possibility of carrying out extensive series of tests on the otherwise fully prepared charges, e.g. as follows: A certain mass loading is applied to a first fully prepared charge, a test is carried out with this charge, i.e. the projectile is formed and then analyzed. A changed mass loading can then be applied to the next corresponding identical charge, the projectile formed and then analyzed. In this way, the projectile formation / mass loading can be optimized iteratively. Loading, i.e. handling of explosives, is then no longer necessary during the corresponding series of tests, so that these can be carried out particularly safely and quickly in order to examine different mass loadings for their effect on formed projectiles.

The invention is based on the following findings, observations and considerations and also has the following preferred embodiments. These embodiments are sometimes referred to as "the invention" for the sake of simplicity. The embodiments can also contain parts or combinations of the above-mentioned embodiments or correspond to them and/or possibly also include embodiments not previously mentioned.

According to the invention, a fine tuning of a projectile / EFP results.

The invention is based on the following basic idea: The design of the EFP (compared to a non-existent mass coverage) can be modified by means of a particularly inert mass coverage of defined mass surface density on an EFP liner (projectile coverage). Instead of adjusting the (projectile) coverage geometry itself, the dynamics of each liner element (projectile section) in the detonative acceleration phase are corrected via the additional mass (mass section) above this element, resulting in an adjustment in the EFP shape. To this end, the mass coverage in particular is adjusted iteratively, e.g. through tests and/or simulation.

The coating geometry itself (projectile coating, with the associated manufacturing methods and tools) can remain unchanged. Inert mass coatings on the outside (side facing away from the explosive) of the EFP liner can be attached/removed/modified even after loading. Test loops can thus be carried out more quickly and easily, and optimizations are easier to carry out.

An additional degree of freedom is used in the design and optimization of EFPs. In terms of manufacturing technology, the rotational symmetry can be broken simply by applying the mass in a non-rotationally symmetrical manner, e.g. only in circle segments. This could, for example, provide advantages in terms of fin formation on the projectile.

• 1 eine erfindungsgemäße Ladung im Querschnitt,
• 2 eine Draufsicht auf die Massenbelegung aus 1 in Richtung des Pfeils II mit deren radialem Dickenverlauf,
• 3a eine alternative Massenbelegung,
• 3b eine weitere alternative Massenbelegung, und
• 3c eine weitere alternative Massenbelegung in einer Darstellung gemäß 2.

Further features, effects and advantages of the invention emerge from the following description of a preferred embodiment of the invention and the attached figures. Each of these shows a schematic principle sketch:

• 1 a charge according to the invention in cross section,
• 2 a top view of the mass occupancy 1 in the direction of arrow II with its radial thickness profile,
• 3a an alternative mass occupancy,
• 3b another alternative mass occupancy, and
• 3c another alternative mass allocation in a representation according to 2 .

1 shows a charge 2 for forming a projectile 4. The charge 2 contains a base body 6. This contains an explosive 8 and a dam 10 in the form of a housing. The charge 2 has a central longitudinal axis 12 and is constructed rotationally symmetrically around it. The dam 10 is designed in the basic shape of a straight circular cylinder, pot-shaped with a pot opening 14. Thanks to its pot-like shape, the dam 10 defines a blasting direction 16 parallel or along the central longitudinal axis 12, in which direction a detonation / conversion of the explosive 8 or a progression of a detonation nation front. A wave guide 18 is optionally arranged in the explosive 8, which can transform a spherical detonation wave / detonation front in the explosive 8 into a flat detonation front in the region of the pot opening 14 in a manner not explained in more detail.

The explosive 8 has a basic shape of a straight circular cylinder to match the dam 10. In the direction of the blasting direction 16, the explosive 8 or the cylinder shape has a front face as a concave surface / indentation. An ignition 20 is provided to trigger the deposition of the explosive 8.

A projectile coating 22 or EFP coating / EFP liner is arranged or applied to the explosive 8 at the pot opening 14 or in the blasting direction 16. Explosive 8 and projectile coating 22 are basically designed together to transform the projectile coating 22 in the blasting direction 16 into the projectile 4 when the explosive 8 is implemented. This in the 1 shown in dashed lines. “Basically” is to be understood as meaning that initially a 1 The mass occupancy 28 shown is ignored. The basic processes considered as follows are therefore indicated by dashed lines.

At a time t0, the explosive 8 is ignited. The projectile coating 22 is accelerated in the blasting direction 16 out of the pot opening 14 and is thereby deformed. At times t1 and t2, intermediate shapes 24a', 24b' are formed. At time t3, the projectile 4' is formed in its final shape 26 and flies further in the blasting direction 16.

In reality, however, the mass coating 28 is applied to a side 30 of the projectile coating 22 facing away from the explosive 8. Since the mass coating 28 is present, it must be accelerated together with the projectile coating 22 or by or through it when the explosive 8 is deployed. Compared to the imaginary absence of the mass coating 28, the acceleration of the projectile coating 22 is therefore changed or influenced by the mass coating 28:

In this case, the projectile 4 takes on a different shape compared to the dashed line or compared to the projectile 4'. At the identical times t1 to t3, the projectile 4 therefore takes on a different shape compared to the imagined situation without mass occupancy 28, and thus different intermediate shapes 24a,b and a different final shape 26.

The reason for this is: The respective projectile sections 32a,b of the projectile loading 22 (indicated by dashed lines, see also 2 ) are covered by different mass sections 34a,b of the mass coverage 28. The projectile sections 32a,b and mass sections 34a,b are chosen arbitrarily here to explain the basic principle, in fact there is an infinitesimal subdivision into smallest sections or a continuously different mass density in the respective concentric mass sections, see 2 below).

The different mass coverage 28 means that these projectile sections 32a,b are affected differently in their acceleration compared to the situation with no mass coverage 28. The acceleration of the projectile section 32a is thus slowed down less by the mass section 34a with a lower mass density (thinner layer) than the projectile section 32b. This is because the latter has to accelerate the mass section 34b with a higher mass density (thicker layer) and thus more mass. This leads to a different shape of the projectile 4 compared to the (imaginary) projectile 4'.

The entire mass occupancy 28 (which is not further shown at times t1 to t3) does not become part of the projectile 4, but serves merely as a mass delay means for its formation.

The mass coating 28 is here arranged or applied as a coating 36 of the projectile coating 22 directly, i.e. without the interposition of other layers on the projectile coating 22.

2 shows the top view of 1 in the direction of arrow II before the detonation of the explosive 8. The mass coverage 28 is shown. Symbolically shown is the course of its thickness D (measured in the direction of explosion 16) over the radius r (see also 1 ). The mass coverage 28 therefore has areas of different mass density, each viewed in the direction of explosion 16. The areas are again symbolically or arbitrarily identified here as just two different mass sections 34a,b. In fact, as can be seen from the curve of the thickness D over the radius r, infinitesimal concentric circular rings around the central longitudinal axis 12 already have different thicknesses D and thus different mass densities. The different mass density is achieved by the mass coverage 28 having different thicknesses D in the direction of explosion 16. In the embodiment shown here, the mass density of the mass coverage 28 is therefore rotationally symmetrical with respect to the central longitudinal axis 12.

The mass coating 28 is inert here, i.e. not made of energetic material. In this case, the mass coating 28 consists of a plastic which was printed directly onto the projectile coating 22 using a 3D printing process.

3a shows a top view in the direction of arrow II of an alternative charge 2. The base body 6, explosive 8 and projectile coating 20, i.e. the entire charge 2 with the exception of the mass coating 28, are identical to the 1 and 2 Only the mass coverage 28 is changed. This is limited here to four specific mass sections 34a (hatched in the figure). Thus, only the corresponding projectile sections 32a are covered by mass coverage 28. The four projectile sections 32b, on the other hand, are not covered by mass coverage 28. In other words, their mass density is zero there. Here, the mass coverage 28 is limited to four circle segments 38.

3b shows an alternative embodiment of a mass occupancy 28. In a modification to 2a Here, a complete central circle 40 is designed without mass coverage 28. The circle segments 38 from 2a with mass allocation 28 are thereby reduced to circular ring segments 42.

3c shows another alternative embodiment of a mass allocation 28, which here comprises a total of 4 circular segments 44 in addition to the 4 circular ring segments 42 of 3b is distributed.

The remaining, non-hatched areas of the projectile occupancy 22 in the 3a -c are therefore not occupied by mass occupancy 28.

The 3a -c lead to differently shaped projectiles 4 (not shown) despite otherwise identical charges 2, i.e. except for the mass loading 28.

List of reference symbols

2

charge

4

projectile

6

Base body

8th

explosive

10

Insulation

12

Central longitudinal axis

14

Pot opening

16

Blast direction

18

Shaft control

20

ignition

22

Projectile occupancy

24a,b

Intermediate form

26

Final shape

28

Mass occupancy

30

Side (facing away)

32a,b

Projectile section

34a,b

Mass section

36

Coating

38

Circle segment

40

Circle

42

Circular ring segment

44

Circle segment

t0-3

time

D

thickness

r

radius

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely to provide the reader with better information. The list is not part of the German patent or utility model application. The DPMA accepts no liability for any errors or omissions.

Cited non-patent literature

• "Wikipedia, 'Projectile-forming charge', website, https:// de. wikipedia. org/ wiki/ Projectile_forming_charge, accessed on August 11, 2022" [0002]

Claims (15)

Charge (2) for forming a projectile (4), - with an explosive (8) forming a base body (6) of the charge (2), - with a projectile coating (22) arranged on the explosive (8) for forming the projectile (4), - wherein the explosive (8) and the projectile coating (22) are jointly designed to transform the projectile coating in a blasting direction (16) into the basic projectile (4') when the explosive (8) is moved, - with a mass coating (28) which is arranged on the projectile coating (22) in such a way that at least one projectile section (32a, b) of the projectile coating (22) is influenced in its acceleration by at least one mass section (34a, b) of the mass coating (28) when the projectile (4) is formed compared to an absent mass coating (28). Load (2) to Claim 1 , characterized in that the mass coating (28) is designed such that at least two projectile sections (32a,b) of the projectile coating (22) are influenced differently in their acceleration compared to an absent mass coating (28). Charge (2) according to one of the preceding claims, characterized in that at least part of the mass coating (28) is not part of the formed projectile (4). Charge (2) according to one of the preceding claims, characterized in that the mass coating (28) is arranged on the side (30) of the projectile coating (22) facing away from the explosive (8). Charge (2) according to one of the preceding claims, characterized in that the mass coating (28) is a coating of the projectile coating (22). Charge (2) according to one of the preceding claims, characterized in that the mass coating (28) has mass sections (34a,b) of different mass densities transversely to the blasting direction (16). Load (2) to Claim 6 , characterized in that the mass coating (28) has mass sections (34a,b) of different mass densities transversely to the blasting direction (16) in that it is designed with a different thickness (D) in the blasting direction (16). Load (2) to Claim 6 or 7 , characterized in that the charge (2) has a central longitudinal axis (12) running in the blasting direction (16) and the mass density of the mass coating (28) is not rotationally symmetrical with respect to the central longitudinal axis (12). Load (2) to Claim 8 , characterized in that the mass coverage (28) on different circular segments (44) or circular ring segments (42) has a different mass density with respect to the central longitudinal axis (12). Charge (2) according to one of the preceding claims, characterized in that the mass coating (28) is inert. Load (2) according to one of the preceding claims, characterized in that the mass coating (28) contains or is a foam and/or a plastic and/or a metal. Method for producing the charge (2) according to one of the preceding claims, in which: - the explosive (8) forming the base body (6) of the charge (2) is provided, - the projectile coating (22) for forming the projectile (4) is arranged on the explosive (8), - the explosive (8) and the projectile coating (22) are basically set up together to transform the projectile coating in the blasting direction (16) into the basic projectile (4') when the explosive (8) is converted, - the mass coating (28) is arranged on the projectile coating (22) in such a way that at least the projectile section (32a, b) of the projectile coating (22) is influenced in its acceleration compared to the absent mass coating (28) by at least one of the mass sections (34a, b) of the mass coating (28) when the projectile (4) is formed. Procedure according to Claim 12 , characterized in that the mass coating (28) is produced by a 3D printing process. Method according to one of the Claims 12 until 13 , characterized in that the mass coating (28) is produced on the projectile coating (22). Method according to one of the Claims 12 until 14 , characterized in that the mass coating (28) is attached to the otherwise fully prepared charge (2).

Images