DE8814130U1 - Test projectile for detonators or for assemblies of such detonators - Google Patents

Description

DGH 557 P E
Fi/yB/se

dmx GmbH & Co.

Stephanstrasse 49, 8500 Heidelberg 30

Jfu fld er oder* fi l f frd ttchrtitttoen such

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The invention relates to test projectiles for detonators or for assemblies intended for large-caliber ammunition or for missiles. To date, it has been necessary to use original projectiles to test detonators or assemblies of such detonators for large-caliber ammunition or for rockets. However, this requires a considerable amount of material and is therefore very costly.

Therefore, the invention is based on the task of reducing the cost of testing the reliability of detonators or assemblies of such detonators, which are intended in particular for large-caliber ammunition or for rockets, by not using the corresponding original projectiles, i.e.

are not used, but test bullets.

This object is achieved according to the invention in that the test projectile is designed as a cartridge with a caliber between 20 mm and 40 mm and is provided with stabilizing wings

ia ■· · * mm · «&bgr; «

which are spring-loaded before firing and are arranged in a rest position within the calibre diameter, and which immediately after firing assume a stabilising position which stabilises the trajectory of the test projectile. Such a test projectile can be used as a cartridge in any weapon or in any gas pressure measuring tube of the corresponding calibre which are designed without rifling. As a result, the weapon or the gas pressure measuring tube used for testing purposes is advantageously only exposed to negligible wear, since a large number of corresponding test echoes can be fired with such a weapon or gas pressure measuring tube. Since the test projectile according to the invention can be produced easily and with comparatively low material consumption in comparison to large-caliber original ammunition or in comparison to cartridges in which such detonators are used, the test projectile according to the invention offers the advantage of a considerable reduction in costs for determining the function, i.e. the overall reliability, of detonators or assemblies of such detonators fired with such a test projectile. With such a test projectile it is possible to test both mechanical and pyrotechnic, electrical or electronic detonators for their function and reliability. Likewise, with such a test projectile it is possible to test assemblies belonging to such detonators for function and reliability, so that a wide range of applications for the test projectile arises. The same applies to the functional test for the ignition devices that are considered for the respective ammunition.

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It has proven to be advantageous that the cartridge has a nose section and a tail section that are connected to one another along a predetermined breaking point, with the nose section having a separating device containing the detonator in a central cavity and the tail section being provided with the stabilizing wings. This type of structure of the test projectile results in good flight stability during the flight, which can be between 3000 and 8000 m or lower or higher, and also has the advantage that the structure of the propellant charge allows the firing acceleration of the test projectile to be characterized as to the firing behavior of the large-caliber original projectile, i.e. the large-caliber remaining ammunition or the rocket.

The stabilizing wings are preferably made of a springy sheet metal material and are in the resting position preferably springy by means of a scraper ring

prestressed at a central core section of the I

tail section. When the test projectile, designed as a cartridge, is fired, the stripping ring remains hanging in a cartridge chamber so that the spring preload of the stabilizing wings can be removed, whereby the stabilizing wings move from the rest position, which requires little space, to their spread-out stabilizing position.

In order for the stabilizing wings to only require a small amount of space in the resting position, the stabilizing wings are preferably positioned at least approximately tangentially away from the core section. By designing the test projectile in this way, it is possible to use the test projectile as a cartridge with a small caliber between

20 Tsm and 40 mm in order to be able to fire the test projectile, for example, with a rifleless weapon with a corresponding nominal caliber.

Shell elements can be provided between the stabilizing wings, which rest resiliently against the core section, and the scraper ring. These shell elements serve in particular to protect the stabilizing wings. Preferably, four shell elements are provided evenly distributed around the circumference of the tail section, and have dimensions that correspond to one another. In a preferred embodiment, two shell elements are used, each of which covers half the circumference of the core section of the tail section, which has the stabilizing wings.

The separating device located in the central cavity of the front section preferably contains an ignition delay set. The ignition delay set determines the combustion time of the separating device in a manner known per se.

A pyrotechnic signal tablet can be provided in the area between the nose and tail of the cartridge-shaped test projectile. At the end of the firing section of the ignition delay set, the signal tablet is ignited, so that a flash of light is produced. For this purpose, a fragmentation charge is preferably provided in the central cavity of the nose to ignite the signal tablet and to separate the nose section from the tail section. With the help of this fragmentation charge, the test projectile is split along the predetermined breaking point into the nose section and the tail section, so that the signal tablet, ignited at the same time or immediately afterwards, produces a flash of light, as already mentioned. This makes it possible

It is possible to measure the burning time of the separating device from the muzzle flash to the visible fragmentation flash during the firing process.

The nose section preferably has a tail unit and a

projectile nose, and the tail section is preferably ■ provided at its rear end section with at least one

The sealing ring/each sealing ring consists

vcrsucjssjöiss made of a ^»netctnffmatarial. As a result, the barrel of the weapon or the gas pressure measuring tube, which is designed without rifling, is not significantly stressed when the test projectile is fired, while at the same time achieving the advantage that when the test projectile is fired, with the projectile movement, at least one sealing ring is pressed into the tube and thus a gas seal is created. The/each sealing ring is preferably made of polyamide.

Further details, features and advantages emerge from the following description of an embodiment of the test projectile according to the invention shown in the drawing. It shows:

Fig. 1 a side view of the test projectile in the rest position in an enlarged scale, 25

Fig. 2 a partially cutaway side view of the test projectile according to Fig. 1 in the flight, i.e. stabilization, position,

Fig. 3 is a section along the line XII-III in Fig. 2, and

Fig. 4: Side view of the test projectile in the stabilization position.

(| Fig* 1 shows a test projectile 10 for fuses or for

Assemblies of such fuses which are intended for large-caliber ammunition or for rockets. The test projectile 10 has a nose section 12 and a tail section 14, whereby the nose section has a tail unit 16 and a projectile nose 18. The tail section 14 has nozzle elements 20 arranged along its circumference and a stripping ring 22 which holds the nozzle element on the tail section Γ-4. The tail section 14 is also provided with sealing rings 24 which are preferably made of polyamide.

From Fig. 2 it is apparent that the _tail unit 16 is designed with a central cavity 26 in which a separating device 28 is arranged. When the test projectile 10 is fired, the firing acceleration in the separating device 28 triggers the ignition mechanism and the

The known delay charge present in the separating device 28 is ignited. At the end of the burning section, a bursting charge ignites a signal tablet 30 and simultaneously blows up the front part 12 from the rear part 14 along at least one predetermined breaking point 32 provided between the last-mentioned parts, whereby a flash of light is simultaneously produced by means of the signal tablet 30.

As can be seen from Fig. 3, the tail section 14 of the test projectile 10 is provided with stabilizing wings. The stabilizing wings 32 consist of a resilient sheet metal material and, in the normal rest position of the test projectile 10, rest against a central core section 34 of the tail section 14. The stabilizing wings 32 are fastened to the central core section 34 by means of fastening screws 36, and they protrude from the central core section 34 in

Direction wag. �Agr;&tgr;&igr; δ this way it is possible to place the stabilizing wings 32 in the rest position of the test projectile 10 on the core area 34 in a space-saving manner. With the help of the switching elements 20 or with the help of the stripping ring 22 (see Fig. 1), the stabilizing wings 32 are fixed to the central core section 34 in the rest position of the test projectile 10.

When the test projectile 10 is fired, the sealing rings 24 are pressed against the gun barrel, which is designed without a draft, by the projectile movement, so that they create a gas seal. When fired, the stripping ring 22 remains in the cartridge chamber, so that it releases the shell elements. The following gases expel the stripping ring 22. When it leaves the muzzle of the gun from which the test projectile 10 is fired, the shell elements 20 are released by the elastic spring force, ie by relaxing the stabilizing wings 32, so that the stabilizing wings 32 can assume the flat, stretched position shown in Fig. 3. In this state, the stabilizing wings 32 serve to stabilize the trajectory of the test projectile 10.

Fig. 4 shows the test projectile 10 in the stabilization position during flight. In this position, the stabilization wings 32 attached to the tail section 14, which are attached evenly symmetrically along the circumference of the tail section 14, are in a flat, stretched state. This figure shows the fastening screws 36 and sealing rings 24 used to attach the stabilization wings 32. This figure also shows the nose section 12 with the tail unit 16 and the projectile nose 18.

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The test projectile 10 is prepared, for example, by first gluing the signal tablet 30 into the tail unit 16 and then the separating device 28 (see Fig. 2). The projectile tip 18 is then mechanically firmly connected to the tail unit 16. This can be done by gluing

The cartridge is loaded, for example, by loading a cartridge case of the appropriate caliber for the desired acceleration. The tail section 14 is inserted into a case around the first sealing ring 24 and is attached to the circumferential groove 38 (see figures 1, 2 and 4).

DGH 557 DE
Fi/ie/se

10

A test projectile (10) is described for use with fuzes of this type intended for large-caliber ammunition or for cartridges. The test projectile is a cartridge with a caliber between 20 mm and 40 μm. designed and provided with stabilizing wings (32) which are arranged in a spring-loaded manner in front of the launcher of the test projectile (10) in an outer heave within the diameter of the projectile and which, immediately after firing, stabilize the trajectory of the test projectile (10). Assume a stabilization position. (Figure 2)

Claims (10)

DGH 537 DE { Fi/HB/se Claims i 10 1* Test projectile for ammunition or for assemblies of such ammunition intended for large-caliber ammunition or for rockets, characterized in that the test projectile (10) is designed as a cartridge with a caliber of between 20 and 40 mm and is provided with stabilizing wings (32) which, prior to firing , are spring-loaded and arranged in a vertical position within the caliber diameter, and which, immediately after firing, assume a stabilizing position which stabilizes the trajectory of the test projectile (10). 2. Test projectile according to claim 1, characterized, that the cartridge (10) has a front part and a rear part (14) which are connected to one another along a predetermined breaking point (31), the front part (12) having a separating device (28) containing the igniter in a central cavity (26) and the rear part (14) being provided with the stabilizing wings (32). &Iacgr;&ogr; 3- Test projectile according to claim 1 or 2* characterized in that the stabilizing wings (32) consist of a resilient sheet metal material and in the rest position are resiliently pre-tensioned by means of a stripping ring (22) and rest against a central core section (34) of the rear part (14). 4. Test projectile according to claim 3, characterized in that the stabilizing wings (32) protrude at least approximately tangentially from the core section (34). 5. Test projectile according to at least one of claims 2 to 4, characterized in that shell elements (20) are provided between the stabilizing wings (32) resiliently resting on the X-section (34) and the scraper ring (22). 20 6. Test projectile according to claim 2, characterized in that the separating device (28) located in the central cavity (26) of the nose part (12) contains an ignition delay set. 7. Test projectile according to at least one of the preceding claims, characterized, that in the area between the front part (12) and the rear part (14) of the cartridge-shaped test projectile (10) a pyrotechnic signal tablet (30) is provided. 8. Test projectile according to at least one of the preceding claims, characterized in that a bursting charge is provided in the central cavity (26) of the bow section (12) for igniting the signal tablet (30) and for separating the bow section (12) from the rear section (14). 9. Test projectile according to at least one of the preceding claims, characterized in that the nose part (12) has a tail unit (16) and a projectile nose (18), and that the tail part (14) is provided at its rear end section with at least one sealing ring (24)- 10. Test projectile according to claim 9,
characterized in that the/each sealing ring (24) consists of a plastic material.