DE102022000198A1 - Additively manufactured support structure for a warhead - Google Patents

Abstract

A support structure (2) for a warhead (4) contains a base body (6) made of a construction material and an active mass (16) made of a heavy metal, the base body (6) being set up to accommodate further components of the warhead (4) or to be connected to them, the active mass (16) being materially attached to the base body (6) by a first additive manufacturing process. A warhead (4) contains the support structure (2). Support structure (2), the base body (6) is provided and the active mass (16) is attached to the base body (6) by the first additive manufacturing process.

Description

The invention relates to a warhead and its manufacture.

From the DE 195 24 726 B4 a warhead with a directional active part is known, the directional active part containing at least one layer of rod-shaped and/or cube-shaped active bodies which can be ejected through the corresponding opening in the warhead casing after the warhead casing has been ruptured.

The object of the present invention is to propose improvements in relation to a warhead.

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

The supporting structure contains a base body. This is made of a construction material or consists of this. The supporting structure contains an active mass. This is made of a heavy metal or consists of this. The base body is designed to accommodate other components of the warhead or to be connected to them. In later manufacturing steps of the warhead, other components of the warhead, for example other structural components such as tail units, a projectile head or explosives, fuses, electronic components, etc., are added or attached to or in the base body. A "pick up" happens, for example, when the basic structure has a specific geometric shape, for example, is designed like a pot or a shell, in order to accommodate or enclose components. A "connection" occurs, for example, in that the base body is subjected to machining, in particular, e.g. B. by milling, drilling, introducing threads, undercuts, locking structures, etc. A "setup" of the base body for the measures mentioned is done in particular by its geometric construction and the selection of a material that allows or favors the corresponding processing, e.g. B. allows the introduction of holes / threads in a simple or conventional manner.

The active mass is materially attached to the base body and connected to it by means of a first additive manufacturing process. Subsequently or after attachment, the support structure then has this active mass or the active mass is attached to the base body. In particular, the active mass is or is applied as a one-piece, uninterrupted volume. In particular, the effective mass encloses the base body completely and in the form of a ring in a circumferential direction (relative to the longitudinal axis of the warhead, see below). In this sense, the application of the active mass to the base body takes place over the entire area without gaps. In particular, a single and uninterrupted interface is created at which the base body and active mass are materially connected to one another.

Construction material and active mass differ in particular in that the active mass has a lower machinability than the construction material, in particular it can only be machined (clamping) under more difficult conditions than the construction material, i. H. e.g. B. has increased tool wear, requires an increased cutting force or reduced cutting speed / feed rate, etc.

The support structure forms one, in particular the only, mechanical basic structure of the warhead, which causes its mechanical stability and penetration resistance and which, in particular, absorbs the forces occurring on the warhead when the warhead is fired as intended, for example from a barrel weapon.

According to the invention, active mass is added to a basic structure or the basic body, e.g. B. by powder build-up welding, applied and both components thereby firmly bonded. This creates the supporting structure as a monolithic component made of several materials. The base body and the applied active mass are thus active agent and supporting structure in one.

This results in the advantage that due to the integral connection of the active mass to the base body, both the base body and the active mass contribute to this mechanical stability or absorb corresponding forces. In contrast to known solutions, the base body or construction material no longer has to do this alone. The effective mass thus has a dual function: On the one hand, it still serves to take on a specific effect when the warhead is dismantled, for example to form fragments. On the other hand, however, it now also takes on a task as part of a mechanical carrying or supporting or basic structure of the warhead.

As a result, the total mass of such a system is limited or reduced, or the total mass or part of it (active mass) can be used as active material. Viewed the other way around, the effective mass at least partially also takes on the task of deriving the launch load and penetration load. As a result, the mass or the volume of the base body and thus of the construction material can be reduced overall, which is why the total mass of the support structure and thus of the warhead is reduced or more payload can be accommodated in the warhead with the same mass.

In a preferred embodiment, therefore, as explained above, the support structure is set up such that the effective mass absorbs at least part of the mechanical loads occurring during normal operation of the warhead. The other part of the load is then in particular completely absorbed by the base body. The base body is therefore functionally supported in this respect by the active mass. Proper operation includes a regular launch, in particular firing of the warhead and thus the support structure, in particular from a barrel weapon. The "equipment" for this takes place in particular through the constructive design of the geometry / choice of material etc. in the supporting structure for a specific application etc.

In a preferred embodiment, the construction material is an aluminum material, in particular an aluminum alloy. Among other things, this material is easy to machine, as described above, so that its simple and inexpensive post-processing/further processing is possible in order to finish the warhead. Steel, a nickel-based alloy (e.g. Inconel) or titanium are also possible.

In a preferred embodiment, the heavy metal is a tungsten material, in particular tungsten carbide or pure tungsten. This material has a high density, making it particularly effective as an active substance.

In a preferred embodiment, the first additive manufacturing method is laser build-up welding, which is carried out in particular with the aid of powder, ie powder build-up welding. This method is particularly suitable for producing a corresponding support structure for a warhead, especially in combination with the materials mentioned above.

In a preferred embodiment, the active mass is or will be produced in its final form by the first additive manufacturing method. After the active mass has been applied by the additive process, there is no further change in the shape of the active mass, e.g. B. by machining post-processing, in particular by any shaping post-processing. The application of the active mass by the additive process thus takes place in its final desired shape. This is particularly advantageous since the active mass, as described above, is in particular one that has comparatively poor or low machinability. Post-processing of the applied active mass for its further shaping would therefore be complex, expensive or tedious, if at all possible. On the other hand, as is well known, the additive manufacturing process can be used to produce almost any structure that is difficult or impossible to achieve, in particular, with classic material removal or workpiece processing (turning, milling, drilling, etc.). However, this does not preclude the sometimes necessary processing to the final dimensions.

In a preferred embodiment, the base body is produced at least partially, in particular completely, by a second additive manufacturing process. The second method is preferably carried out before the first method, so that in this respect the base body is finished before the active mass is applied. In particular, a base body can also be provided first, which is supplemented by the second additive manufacturing method, so that a composite body, in particular a one-piece body, results as the base body. In this case, in particular, pre-processing or post-processing of the base/main body is possible, in particular by machining. In particular, the second can be the same as the first additive method. According to this embodiment, there are a number of degrees of freedom in the sequence of different manufacturing steps (classic, additive) in order to produce a base body as economically, quickly and cost-effectively as possible. The shape of the base body can therefore - as explained above - be almost arbitrary.

In a preferred embodiment, at least part of the support structure forms at least part of the—particularly lateral—outer surface of the warhead. The orientations are based on a longitudinal axis or intended flight direction/firing direction of the warhead. The “lateral” outer surface is the peripheral side surface, i.e. the one whose surface normal points in the radial direction in relation to the one longitudinal axis/direction of the warhead or has at least one radial component. As a result, at least part of the support structure forms the outer surface of the warhead. The surface area of the support structure on the surface of the warhead is in particular min at least 20%, 40%, 60%, 80% or 90%. Thus, at least a part of the surface or outer surface of the warhead is already finished by the completion of the support structure. An "outer surface" is to be understood as meaning the outer structural surface of the warhead, with the exception of coatings, paintwork, surface layers, etc., which can still cover the outer surface. In any event, the outer surface is no longer surrounded or covered by another structural layer of the warhead, such as a surrounding structural envelope, etc. An additional outer shell is possible, but without a supporting function.

In particular, part or all of the surface of the heavy metal that is accessible after attachment to the base body forms part of this outer surface. “Accessible” means that it is not a matter of a part of the active mass that is materially connected to the base body. The proportion of the surface of the active material that forms the outer surface is in particular at least 70, 80 or 90%.

In a preferred variant of this embodiment, a surface of the active mass that forms the outer surface is unstructured—in the region of this surface. “Unstructured” is to be understood in such a way that the surface is smooth or even in relation to the dimensions of the warhead, i.e. in the macroscopic sense. In relation to an overall (related to its entire extent) basic shape of the warhead, the entire relevant surface of the effective mass has a shape like a section of a cylinder, barrel body, (truncated) cone, etc. Such surface shapes are particularly suitable for warheads. In particular, the surface therefore has no nubs, grooves, grooves, ribs, edges, etc.

In particular, the transition between the active mass and the base body is smooth, edge-free, kink-free, continuous or locally even; H. Identical tangential planes on the surfaces of the active mass and the base body prevail on both sides at the boundary line in question.

In a preferred embodiment, the support structure, in particular the effective mass, is set up such that the effective mass breaks down into fragments when the warhead is disassembled as intended. The fragments are in particular splinters. In particular, the active mass has predetermined breaking points for this purpose, at which the decomposition into fragments then takes place as intended. Thus, in particular, the above-mentioned double function can be achieved, that the active mass, which mechanically stabilizes the supporting structure, also unfolds its intended combat effect.

In a preferred variant of this embodiment, the active mass has the predetermined breaking points mentioned above, in order to be divided into the fragments there during the disassembly. The predetermined breaking points are formed in that the base body has a negative structure--particularly pointing radially outward with respect to the above-mentioned longitudinal axis. In this case, the negative structure has a negative form of at least some of the predetermined breaking points. The active mass is applied to the negative structure. Due to the areal application, the active mass then takes on a corresponding positive structure, i. H. -shaping on.

This embodiment is particularly useful in combination with the above-mentioned smooth or unstructured outer surface of the active material. The predetermined breaking points formed by the negative structure are thus located only inside the material of the support structure, namely at the one-piece interface between the base body and the active mass. In particular, it can be achieved particularly easily that then on the negative structure, z. B. their radially outward-pointing ribs / webs, a lower material thickness of the active mass is created, which leads to the corresponding predetermined breaking points.

In a preferred variant of this embodiment, the negative structure has—particularly intersecting—webs pointing radially outwards. The connection of the active mass with the negative structure results in a structural weakening as a positive form corresponding to the negative structure, e.g. B. notches, depressions, grooves, grooves, etc. in the active mass. The webs run, in particular, crossed, in particular in the longitudinal direction and circumferential direction of the warhead and/or have a triangular cross section, in particular in their direction of extent, possibly with a flattened tip. These shapes therefore lead to at least approximately V-shaped indentations, i. H. Predetermined breaking points in the active mass. Instead of in the longitudinal and circumferential direction, the webs can also run obliquely, z. B. 45 ° to the longitudinal axis of the warhead. This can have advantages for the disassembly and the load bearing.

In particular, through the second additive manufacturing process of the base body, a complex-shaped negative structure/shape can be produced on the base body in a particularly simple manner. B. by turning or milling an alternative body would be difficult or impossible to produce. As a result, predetermined breaking points with a particularly favorable structure can also be produced in the active mass.

The predetermined breaking points in the active mass thus result automatically, so to speak, purely by (area-wide) attaching the active mass to the base body.

The object of the invention is also achieved by a warhead according to claim 13 with the support structure explained above.

The warhead and at least some of its possible embodiments and the respective advantages have already been explained in connection with the support structure according to the invention.

The object of the invention is also achieved by a method according to claim 14 for producing the support structure explained above. In the method, the base body is provided. Furthermore, the active mass is attached to the base body in a materially bonded manner using the first additive manufacturing process.

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

Accordingly, there is also a method according to claim 15 for the production of a warhead, in which the supporting structure is produced according to the method mentioned.

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

The invention is based on the following findings, observations and considerations and also has the following embodiments. The embodiments are sometimes also 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 optionally also include embodiments that have not been mentioned before.

The invention is based on the finding that competing design criteria prevail in a warhead, namely “high effective mass vs. firing load (=strength) vs. low total mass vs. high proportion of energetic material”.

The invention is based on the observation that in practice, assembly groups have often been used to manufacture a warhead. This requires many components that have to be assembled together. In doing so, e.g. B. preformed fragments (parts of the active mass) mounted / fixed in an assembly. This assembly is then fixed to a base body that alone absorbs the firing load. However, the assembly of the fragments does not contribute, or at least not significantly, to the removal of the mechanical loads on the warhead (inter alia because of a non-material connection with the base body). This known basic structure of a warhead thus contains a lot, ie a large proportion, of supporting structure (base body) which in turn does not contribute, or at least not significantly, to the effect (effective mass). So far, individual parts or components of the warhead have essentially been joined, in particular without connecting them to one another in a materially bonded manner.

The basic idea of the invention is to create an only partially mechanically supporting structure (base body) of a warhead, which consists of a structural material. This is directly connected, in particular welded, to a material (active mass) that is intended or necessary for the effective power of the warhead by means of an additive manufacturing process. For example, a base body made of aluminum as a construction material (comparatively easy to process) is coated with tungsten carbide or tungsten (heavy metal, high density, comparatively difficult to process) as an active substance using powder build-up welding as an additive manufacturing process, i.e. firmly bonded. The basic structure is thus supported and the mechanical loads on the warhead, especially when it is fired, are also borne by the effective mass.

According to the invention, this results in a fully integrated composite warhead. The combination of base body and active mass can therefore be described as "self-supporting".

The invention is particularly suitable for use in a projectile casing and/or a fragmentation warhead.

In particular, so-called "3D printing" processes are used as additive manufacturing processes.

• 1 eine perspektive Darstellung einer Tragstruktur,
• 2 einen Querschnitt durch die Tragstruktur aus 1 entlang der Ebene II-II.

Further features, effects and advantages of the invention result from the following description of a preferred exemplary embodiment of the invention and the attached figures. Show, each in a schematic principle sketch:

• 1 a perspective representation of a supporting structure,
• 2 a cross-section through the supporting structure 1 along level II-II.

1 shows a support structure 2, which forms the basis for a warhead 4 to be further manufactured, not shown in detail and only indicated by dashed lines.

The support structure 2 has a base body 6, which here has approximately the shape of a pot, namely a bottom 8 and a side wall 10 as well as an opening 12 on the end face. The support structure 2 or its pot shape extends concentrically to a longitudinal axis 14 of the entire warhead 4, which also corresponds to its intended firing direction from a barrel weapon and flight direction. The base body 6 consists of a structural material, here an aluminum alloy.

The support structure 2 also contains an active mass 16, which consists of a heavy metal, here tungsten. In the production of the support structure 2, the base body 6 was first provided or manufactured. The active mass 16 was then attached to the base body 6 over the entire surface in a materially bonded manner using a first additive manufacturing process, here powder build-up welding.

The geometries of the base body 6 and the active mass 16 are selected such that the active mass 16 completely or flushly fills an incision 18 in the base body 6 or its side wall 10 and thus seamlessly supplements or completes the pot shape mentioned above.

The incision 18 runs in the circumferential direction around the longitudinal axis 14 in the form of a ring or in the manner of a straight circular cylinder jacket, the incision 18 in the manner of a corresponding circumferential groove. However, a radially inward base 20 or groove base of the incision 18 is not smooth, but has a negative structure 22 . The negative structure 22 is formed by webs pointing radially outward with respect to the longitudinal axis 14 . The webs are made up of webs running in the circumferential direction in the form of transverse webs 24 and webs running parallel to the longitudinal axis 14 in the form of longitudinal webs 26.

FIG. 2 shows a cross section through the support structure 2 1 along level II-II. It can be seen here that the transverse webs 24 have a triangular cross-section 28 with respect to their direction of extension, here the circumferential direction. The longitudinal webs 26 are, as in 1 recognizable, similar - performed to the transverse webs 28 - only in the longitudinal direction.

In order to produce this negative structure 22 in a particularly simple manner, the base body 6 is also produced by a second additive manufacturing process or is provided as a result, as mentioned above.

Through the above-described application or application of the active mass 16 to the base body 6, a corresponding positive form is formed on or in the active mass 16, which leaves the negative structure 22—as an impression, so to speak—in the active mass 16. The result of this is a network of V-shaped incisions 30 running in the longitudinal direction and circumferential direction in the active mass 16. The incisions 30 form predetermined breaking points 32 in the active mass 16.

After completion of the warhead 4 is filled with explosives, not shown. When it is implemented when the warhead is deployed, the entire support structure 2 and in particular the active mass 16 is dismantled. The disassembly now takes place at the predetermined breaking points 32. The fragmented active mass 16 is thus broken down into individual fragments 34, here splinters. These are in 1 indicated by dashed lines.

A part of the support structure 2, namely its radially outward-pointing surface of the side wall 10, forms part of the outer surface 11 of the warhead 4 even after its completion. This entire outer surface 11 including the surface 36 of the active mass 16 is unstructured, namely smooth or " flat" (here in the sense of the ideal straight circular cylinder shape).

The integral connection of active mass 16 and base body 6 results in a fully integrated, one-piece component as a support structure 2, which is set up in its entirety to withstand the mechanical forces that occur during normal operation, here firing the warhead 4 from a barrel weapon or penetrating a target structure to take on loads. The dimensions are such that neither the base body 6 nor the active mass 16 alone could absorb these loads. The support structure 2 is only dimensioned by the connection of the two elements.

The active mass 16 is no longer reworked after it has been applied to the base body 6, ie the active mass 16 is produced in its final form by the additive manufacturing process. Only the warhead is finally painted over, which should not be understood here as post-processing. Also forms the corresponding paint in vorlie In the current sense, there is no further layer outside the "outer wall" of the warhead 4 in the form of the support structure 2.

Reference List

2

supporting structure

4

warhead

6

body

8th

Floor

10

Side wall

11

Outer Surface (Warhead)

12

opening

14

longitudinal axis

16

active mass

18

incision

20

Ground

22

negative structure

24

cross bar

26

longitudinal web

28

cross-section

30

incision

32

predetermined breaking point

34

fragments

36

surface (active mass)

QUOTES INCLUDED IN DESCRIPTION

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

Patent Literature Cited

• DE 19524726 B4 [0002]

Claims (15)

Carrying structure (2) for a warhead (4), with a base body (6) made of a construction material and with an active mass (16) made of a heavy metal, the base body (6) being set up to accommodate further components of the warhead (4). or to be connected thereto, the active mass (16) being attached to the base body (6) in a materially bonded manner by means of a first additive manufacturing process. Support structure (2) after claim 1 , characterized in that the supporting structure (2) is set up such that the active mass (16) absorbs at least part of the mechanical loads occurring during normal operation of the warhead (4). Supporting structure (2) according to one of the preceding claims, characterized in that the construction material is an aluminum material, steel, a nickel-based alloy or titanium. Supporting structure (2) according to one of the preceding claims, characterized in that the heavy metal is a tungsten material. Support structure (2) according to one of the preceding claims, characterized in that the first additive manufacturing process is laser build-up welding. Carrying structure (2) according to one of the preceding claims, characterized in that the active mass (16) is produced in its final form by the first additive manufacturing process. Support structure (2) according to one of the preceding claims, characterized in that the base body (6) is at least partially produced by a second additive manufacturing process. Support structure (2) according to one of the preceding claims, characterized in that at least part of the support structure (2) forms at least part of the outer surface (11) of the warhead (4). Support structure (2) after claim 8 , characterized in that the outer surface (11) of the warhead (4) forming surface (36) of the active mass (16) is unstructured. Support structure (2) according to one of the preceding claims, characterized in that the support structure (2) is set up so that the active mass (16) breaks down into fragments (34) when the warhead (4) is dismantled as intended. Support structure (2) after claim 10 , characterized in that the active mass (16) has predetermined breaking points (32) in order to be divided into the fragments (34) during disassembly, the predetermined breaking points (32) being formed in that the base body (6) has a negative structure (22 ) having a negative form of at least part of the predetermined breaking points (32) and the active mass (16) is applied to the negative structure (22). Support structure (2) after claim 11 , characterized in that the negative structure (22) has intersecting webs (24, 26) pointing radially outwards. Warhead (4) with a support structure (2) according to one of the preceding claims. Method for producing a supporting structure (2) according to one of the preceding claims, in which - the base body (6) is provided, - The active mass (16) is attached to the base body (6) in a cohesive manner by the first additive manufacturing process. Method for manufacturing a warhead (4). Claim 13 , In which the supporting structure (2) according to the method Claim 14 will be produced.

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