WO2009018901A1

WO2009018901A1 - Drive or guide cage and method for securing such cages

Info

Publication number: WO2009018901A1
Application number: PCT/EP2008/005799
Authority: WO
Inventors: Thomas Heitmann
Original assignee: Rheinmetall Waffe Munition Gmbh
Priority date: 2007-08-09
Filing date: 2008-07-16
Publication date: 2009-02-12
Also published as: EP2176621A1; KR20100068376A; DE102007037700A1; US20120000390A1

Abstract

In order to maintain predetermined tolerance conditions for the front guide region (7) in a simple manner without reconditioning even if a drive or guide cage (5) is made of plastic, the invention proposes beginning with a premounted cage shot (1), wherein the cage segments directly adjacent to one another on the circumferential sides surrounding the shot body are selected such that the cage (5) has an outer diameter in the front guide region (7) that is less than the predetermined target diameter (Do). The adjustment of the diameter of the guide region (7) then occurs subsequently, for example, by the insertion of an insert (12.1) designed in the shape of a bushing, said insert having a conical outer surface (13), into an annular gap (11) remaining between the shot body (2) and the segments (19, 20) of the support wall (8) of the cage (5).

Description

DESCRIPTION

Driving or guiding cage and method for fixing such cages

The invention relates to a drive or guide cage and a method for fixing such cages, in particular a training projectile.

A sabot projectile is known for example from DE 43 30 417 C2. It consists of a sub-caliber projectile body and a Führungsstreibkäfig, wherein the sabot consists essentially of a rear-mounted traction sheave, on which the rear portion of the projectile body is supported, and two surrounding the projectile body, half-shell-shaped sabot segments. The Führungsstreibkäfig has in the front region on an outside circumferential projecting guide portion and comprises in the front to middle portion of the projectile body a radially inwardly extending support wall having a central opening through which the projectile body protrudes. Both for reasons of weight and reasons of ease of manufacture, the guide friction cage is preferably made of carbon or glass fiber reinforced plastic and can therefore be produced very inexpensively by injection molding or compression molding in larger series.

However, compliance with the predetermined small tolerances of the front guide region of the sabot, with which the sabot projectile is supported on the inside of the corresponding weapon barrel, has proven to be problematic in the production of such sabot projectiles made of plastic. Thus, for example, in a 120 mm tank ammunition, the corresponding outside diameter of the guide region should be between 119.65 and 1.193.83 mm, which is virtually impossible to achieve in the case of injection-molded parts or molded plastic parts without costly reworking.

The invention has for its object to show a drive or guide cage, with which it is possible in a simple manner, given tolerance conditions in particular dere for the front guide area of the above-mentioned sabot projectiles to comply without rework, even if the drive or guide cages are made of plastic and produced by injection molding or compression molding.

This object is achieved with respect to the cages by the features of claim 1 and in terms of the method by the features of claim 7. Further, particularly advantageous embodiments of the invention disclose the dependent claims.

The invention is based essentially on the idea that it is assumed that a preassembled propellant or guide cage, in which the circumferentially directly adjoining and the projectile body comprising driving or guiding segments are chosen such that the cage has an inner diameter in the front guide region, which is slightly larger than the outer diameter of the arrowhead and that an annular gap remains between the projectile body and the inner surface of the central opening. Starting from this preassembled sabot projectile, the diameter of the guide region is then adjusted to the predetermined desired value by introducing a so-called adjusting element into the annular gap, from the front side of the guide friction cage.

For precise adjustment of the diameter of the front guide region, the preassembled structural unit can be inserted in the region of the guide region in an annular assembly tool (caliber setting tool) whose inner diameter corresponds to the predetermined nominal value diameter of the guide region.

The non-positive fixing of the adjusting element in the central opening can be effected by an adhesive or welded connection of the adjusting element with the supporting wall.

For non-positive connection of the cage segments of the cage with each other, each of the cage segments can be circumferentially provided with at least one tab-shaped part which is glued into a corresponding recess of the respective adjacent cage segment or also connected by means of a welded connection.

In a preferred embodiment of the invention, the cage floor produced by the method according to the invention is a projectile whose Cage preferably comprises only two half-shell-shaped cage segments. The adjusting element is preferably made of a deformable plastic material, so that this material deforms during slow insertion into the annular gap and thus tolerances the contours of the projectile body and the cage segments (segments of the support wall) adapts.

As a setting element, a bush-shaped insert with a conical outer surface can be used. The bush-shaped insert may consist of two half-shell-shaped parts, wherein the separating lines located between the two parts connect radially to the dividing lines of the two halves of the supporting wall of the sabot segments. But it can also be integrally formed and in the areas which have radially adjacent to the dividing lines of the two halves of the support wall of the sabot segments predetermined breaking points. The insert is pushed into the annular gap until the outer diameter of the front guide region corresponds to the predetermined nominal value diameter due to the pressing apart of the segments of the support cage of the sabot supporting the insert. Subsequently, both the adjustment in the annular gap are then fixed non-positively, and the cage segments of the cage are positively connected to each other.

It has proven to be advantageous if the insert is designed as a collar, so that an axial displacement of the insert is limited by the federal government.

Alternatively, the adjustment can be formed by a highly deformable silicone rubber (Shore 40), which is modeled on the contours of the support wall of the guide cage and on the one hand surrounds the support wall from above and below, on the other hand presses against the projectile. By covering the assembly tool deforms the clip or clasp-like attachment between the half-shells and the projectile.

A major advantage of using deformable plastic material (eg rubber) for the adjustment elements is that no mechanical reworking is necessary and the tolerances of the molding tool can be individually compensated for on the cage floor, whereby the molding tool no longer has to be designed so precisely. Further details and advantages of the invention will become apparent from the following, with reference to figures explained embodiments.

Show it:

1 shows the longitudinal section through an inventive Treib- particular Führungsungskä- figile, in which the cage segments of the cage are already pushed so far apart that the front guide portion of the cage has a predetermined setpoint diameter;

FIG. 2 shows a cross section through the cage floor shown in FIG. 1 along the section line indicated there by H -I;

3 shows a section along the in Fig.2 III-III designated cutting line and

4 is a perspective view of the cage floor shown in Figure 1,

5 shows a further variant of a setting element,

Fig. 6, the introduction of the adjustment of Fig. 5 in the guide cage floor.

In FIGS. 1 and 4, 1 denotes a guide cage floor, which is, for example, a 120 mm tank bullet, which fulfills the function of a so-called sabot (alternatively, it could also be a sabot). The cage floor 1 comprises a sub-caliber projectile body 2 and a substantially hollow-cylindrical guide cage 5 consisting of two shingles (guide cage segments) 3, 4. In the rear area, a traction sheave (pusher plate) 6 is provided in the guide cage 5, on which the projectile body 2 is supported at the rear.

The existing example of plastic guide cage 5 has in its front region a circumferential, outside projecting guide portion 7 for support on the pipe inner wall of a gun barrel, not shown. In addition, a radially inwardly extending (segmented) support wall 8 is provided in the front region of the guide cage 5, which has a central opening 9 through which the projectile body 2 is passed. Between the inner surface 10, the central opening 9, the support wall 8 and the projectile body 2 is an annular gap 11, in which a bush-shaped insert 12.1 inserted as adjusting 12 made of a highly deformable plastic material with a conical outer surface 13 and a collar 14 and with support wall 8 is positively connected (see also Fig.3). In this case, the bush-shaped insert 12.1 consists of two half-shell-shaped parts 15, 16 (Figure 2), wherein the dividing joints 17 located between the two parts 15, 16 radially adjoin the parting lines 18 of the two segments 19, 20 of the support wall 8.

To adjust the outer diameter of the guide portion 7 very accurately to the predetermined target value, the cage segments 3, 4 are selected such that they are arranged radially displaceable (before they are non-positively connected) and in the pushed together state (ie before inserting the insert into the Annular gap) in the front guide portion 7 have an outer diameter (of eg 119.7 mm), which is smaller than the predetermined setpoint diameter Do (of eg 119.8 mm).

The exact adjustment of the outer diameter of the guide portion 7 is then such that is introduced from the front of the guide cage 5 from the bush-shaped insert 12.1 in the relatively narrow annular gap 11 and axially displaced until such time as pushed apart by the sliding on the insert 12.1 Segments 19, 20 of the support wall 8, the outer diameter of the front guide portion corresponds to the predetermined setpoint diameter Do. For this purpose, the front guide portion 7 can be inserted into an annular mounting tool (not shown), whose inner diameter corresponds to the nominal diameter Do of the guide portion 7.

Then both the insert 12.1 with the support wall 8 and the cage segments 3, 4 are non-positively connected to each other, for example by means of an adhesive connection. For non-positive connection of the cage segments 3, 4 of the guide cage 5, each of the cage segments 3, 4 circumferentially provided with a tab-shaped part 22 which is glued or welded into a recess 23 of the corresponding adjacent cage segment 4, 3.

Alternatively, according to FIG. 5, the adjusting element 12 can be designed as a clip-like or clasp-like mounting. set 12.2 be pushed over the support wall 8, which fills the narrow annular gap 11. The article 12.2 has a shape adapted to the support wall 8, wherein a lower and an upper surface 12.2.1, 12.2.2 enclose the support wall 8, while 12.2.3 standing between the two sides 12.2.1, 12.2.3 against the projectile 2 is pressed (Fig. 6).

The attachment 12.2 presses the cage half shells 3, 4 to the outside. By coating the caliber adjustment tool (not shown in detail), the attachment 12.2 deforms between the half-shells 3, 4 and the projectile 2. Subsequently, the half-shells 3, 4 are firmly connected to each other. Also, this essay 12.2 is like the insert 12.1 preferably designed in two or more parts.

The insert 12.1 or attachment 12.2, i.e., the adjusting element 12, as a molded element also have good damping properties in the pipe passage.

Alternatives for connecting the half-shells or cage segments 3, 4 would be the use of bolts that are beaded and / or welded, a screw with predetermined breaking points or by additional elements, such as adhesive tabs.

LIST OF REFERENCE NUMBERS

1 drive or guide cage floor

2 projectiles

3.4 half-shells, cage segments

5 drive or guide cage

6 traction sheave

7 leadership area

8 support wall

9 central opening

10 inner surface

11 annular gap

12 adjustment element

12.1 Use

12.2 essay

13 outer surface

14 fret

15.16 parts

17 parting line (insert)

18 parting line (retaining wall)

19,20 segments 2 tab-shaped part 3 recess

Claims

1. cage cage (1) with a drive or guide cage (5) consisting of at least two cage segments (3, 4), characterized in that between the projectile body (2) and the cage segments (3, 4) an adjustment member (12) involved is.

2. cage floor according to claim 1, characterized in that the cage (5) comprises only two half-shell-shaped cage segments (3, 4).

3. cage floor according to claim 1 or 2, characterized in that the adjusting element (12) consists of a deformable plastic material.

4. cage floor according to one of claims 1 to 3, characterized in that the adjusting element is a bush-shaped insert (12.1).

5. cage cage according to claim 4, characterized in that the bush-shaped insert (12.1) is formed in one or more parts and in the regions which radially to the parting lines (18) of the two segments (19, 20) of the supporting wall ( 8), have predetermined breaking points.

6. cage floor according to claim 4 or 5, characterized in that the bush-shaped insert (12) consists of two half-shell-shaped parts (15, 16), wherein the between the two parts (15, 16) located joints (17) connect radially to the parting lines (18) of the two segments (19, 20) of the support wall (8) of the cage (5).

7. cage cage according to one of claims 1 to 5, characterized in that the insert (12) is designed as a collar bushing.

8. cage cage according to claim 1, characterized in that the adjusting element (12) is an attachment (12.2), which can be slipped over the support wall (8) in the manner of a clip or a clasp.

9. cage cage according to one of claims 1 to 8, characterized in that the cage segments (3, 4) are made of plastic.

10. A method for fixing a cage floor on a subcaliber projectile body (2) and a segmented, substantially hollow cylindrical drive or guide cage (5), the outside has a peripheral guide portion (7) in the front region and in the front to middle portion of the projectile body ( 2) comprises a radially inwardly extending support wall (8) comprises, which has a central opening (9) through which the projectile body (2) protrudes, characterized in that the projectile body (2) first introduced into the cage (5) is, wherein the circumferentially adjoining cage segments (3, 4) are chosen such that they are arranged radially displaceable and are in the collapsed state, in which a front guide portion (7) of the cage (5) results whose outer diameter is smaller than a predetermined setpoint diameter (Do) and that between the projectile body (2) and the inner nfläche (10) of the central opening (9) of the support wall (8) remains an annular gap; then in the annular gap, from the front of the cage (5), an adjusting element (12, 12.1, 12.2) is inserted into the annular gap (11), and then both the adjusting element (12, 12.1, 12.2) in the annular gap (1 1) non-positively fixed and the cage segments (3, 4) of the cage (5) are positively connected to each other.

11. The method according to claim 10, characterized in that for adapting the diameter of the front guide region (7) to the setpoint diameter (Do) from the projectile body (2) and cage (5) existing preassembled unit in the region of the guide region (7) in an annular Assembly tool is inserted, whose inner diameter corresponds to the nominal diameter (Do) of the guide portion (7).

12. The method according to claim 10 or 11, characterized in that for frictional fixing of the adjusting element (12, 12.1, 12.2) of this with the support wall (8) is glued or welded.

13. The method according to any one of claims 10 to 12, characterized in that for frictional connection of the cage segments (3, 4) of the cage (5) each of the cage segments (3, 4) is peripherally provided with at least one tab-shaped part (22), which is glued into a recess (23) of the corresponding adjacent cage segment or connected by means of a welded joint.

14. The method according to any one of claims 10 to 13, characterized in that when using a bush-shaped insert (12.1) as an adjusting element (12) of this as long as in the annular gap (11) is pushed until the sliding apart on the use ( 12.1) supporting segments (19, 20) of the support wall (8), the outer diameter of the front guide portion (7) corresponds to the predetermined setpoint diameter (Do).

15. The method according to any one of claims 10 to 13, characterized in that when using a clip or clasp-like attachment (12.2) as adjusting element (12) by the coating of a mounting tool, the attachment (12.2) between the cage segments (3, 4 ) and the projectile (2) deformed.