NL8503490A - Combustible cartridge for large calibre weapon - has charge enclosing star shaped core with holes in perforated arms filled with ignition material - Google Patents

Abstract

Inside the loading chamber (1) of a large calibre weapon is a cartridge (3) with its wall enclosing the driving charge (5). At the centre is a core (6) with both ends open. This incorporates longitudinal folds forming a star shape with pointed radial arms. These folds are perforated and the holes (15) are filled with a pyrotechnical substance (16), reacting to heat in a highly sensitive manner. Only the central parts of the triangular folds are coated with the substance, not the ends (7) which slope outwards at an angle.

Description

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Ignition system for combustible cardoons.

The invention relates to an ignition system for combustible cartridges with a propellant charge igniter on the weapon side and a reinforcement lock on the cartridge side.

5 The ignition of propellant charge powders must reproduce reproducibly within a short time, namely in milliseconds, a stable combustion, otherwise no proper function of the weapon or a reproduction | cable output capacity, namely muzzle velocity! 10 of the grenade, can be guaranteed.

Since the combustion of propellant charge powders depends strongly on the pressure, the ignition phase at which the normal pressure still prevails is critical, especially with regard to the charge density. Thus, a reproducible pressure build-up becomes more difficult the smaller the charge density. In addition, with a low loading density, the movability of the cartridge or of the modular loads in the cargo space is added. At a certain position of the weapon, the distance between the propellant charge igniter and the propellant charge can be relatively great.

In weapon systems operating with different charges, these problems arise and, for example, in mortars and howitzers from the first to the eighth load, different propellant modules are added.

With an ignition system according to German Pat. No. 2,723,983, the object is achieved of improving the ignition circuit of a propellant charge igniter for sleeve-less cardigans such that both a reduction of the ignition delay time and a reduction in the spread of this delay time is acquired.

To this end, provision is made for the propellant charge igniter to initiate the ignition of at least one combustible projectile, wherein a cartridge bag made of fabric serves as an envelope for a propellant charge of the propellant charge which is arranged in known manner for the tubular or landfill powder. However, this system requires that the sleeve-less "·; = ·. I λ Λ · i. -» * i

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-2- d 't * kardoes provides a target for the combustible projectile. However, this solution is not suitable for a cartridge with a central center tube.

The object of the invention is now the object of the invention to provide an ignition system which, irrespective of the distance between the cartridge and the propellant charge igniter, ensures reproducible ignition of the propellant gunpowder within a range of milliseconds.

According to the invention, this object is now achieved, because the propellant charge igniter has a giver shaft and the cartridge has a receiving gass for igniting the reinforcement gass, while the giver gass has a hot, particulate and enriching generates a beam and the receiving axis has a high input sensitivity and therefore reacts very sensitively when the hot particles get on it.

Further favorable elaborations of the invention are further elucidated hereinafter and are indicated in more detail in the subclaims below. The principle according to the invention is based on a reciprocal pair of pyrotechnic sacks, namely a sender shaft for generating a hot, particle-rich and enriching jet and a receiver sax with a high input sensitivity in the form of a pyrotechnic lacquer.

The transducer is located in the propellant charge igniter. When it is reacted, hot particles are released, which are thrown out so far that they end up on the pyrotechnic seal, namely the receiving seal. Even when the receiving seal is 30 meters away, the reception lock ignited. No special targets are necessary here, because the beam reflects the particles in the center tube because of its conicity.

Since the pyrotechnic axes react independently of the pressure, reproducible ignition is guaranteed even at normal pressure and at low charge density. Due to the intimate contact of the applied pyrotechnic layer from the receiving shaft to the cartridge or the propellant charge module, the transfer of the 40 igniter to the propellant gunpowder is guaranteed with certainty. ”J ϊ» '-3- V .........

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It is important for the generator that the lead oxides in the gun barrel are reduced to lead and thereby act as a lubricant. Wear-causing 5 components are not present. Titanium metal can also be used instead of zirconium metal gunpowder. The sender shaft is also dimensioned in such a way that with a number of cartons arranged in a loading space, these are ignited separately by the sender shaft. The center tube of the cartridge in front serves as guide tube 10 for the beam.

The center tube can herein have a star-shaped cross-section, so that a sector-wise cross-section for the passage of the ignition beam is obtained, which is approximately three times as large as the cross-section according to German Offenlegungsschrift 3,417,739.

This shows a combustible propellant cartridge for large-caliber weapons. The cartridge has a central part open on both sides. In the case of such cartons arranged one behind the other in a cargo space 20 of a weapon, the difficulty arises that the last cartridge is also ignited by the radius of the propellant-charge igniter or of the giver's load. It has been found that partly overlapping star-shaped cross-sections of successive charges nevertheless, an assured ignition of the individual charges and also of the last charge is ensured, since the hot particles of the igniter beam 30 and the hot gases within the star shape find a very large burning surface.

The gas jet can flow freely from the first to the last charge, at least in the size of the circular cross-section and part of the star-shaped cross-section of the middle section.

As a result, sufficient energy is available for each charge for ignition, namely by burning particles which preferably settle in the receiving charge and by the convection of the 40 gases. Due to the conical ignition radius, λ * 5 »» Λ $ '0 ·. v! j v. "-4" sufficient reflective parts of the beam in the middle parts.

The high intensity of the blasting elements which produce the ignition per charge therefore consists of blasting parts irradiating directly on the fire surfaces and of indirect, thus reflecting blasting parts.

The invention has been elucidated on the basis of exemplary embodiments, shown in the drawing, in which:

Fig. 1 is a longitudinal sectional view of a casing-free cartridge ignition system within a weapon loading bay;

Fig. 2 shows an embodiment of a cartridge;

Fig. 3 shows a further embodiment of a cartridge; FIG. 4 is a longitudinal sectional view of a combustible cartridge in the interior of a weapon loading bay;

Fig. 5 is a cross section taken on the line V-V of FIG. 4; and FIG. 6-8 show longitudinal sections about the differences between the other cartons.

According to FIG. 1, a propellant loading cartridge 2 with a transducer shaft 3 is arranged in a movable closing block 1.

The closing block 1 is provided with an ignition channel 4.

In a weapon block 5, which together with the locking block 1 forms part of a weapon, a loading space 6 is arranged with a combustible cartridge 7 and an attachment space 8 for a grenade 9. The loading space 6 has a length such that a number of cartridges 7 can be arranged one behind the other.

Cartridge 7 consists of a combustible material and is thin-walled and provided with head-side cheeks 15 for strength reasons. A central tube 16 has bores 18 filled with the receiving shaft 17 and a reinforcing shaft 20 arranged circumferentially. The propellant charge is indicated by 22.

According to FIG. 3, the inner wall 19 of the center tube 16 is provided with the layer of receiving spindle 17, leaving the end-face wall regions 25 free.

40 When the propellant charge igniter 2 on the known 5 b j 4 j 0 y. Is ignited in a manner, then the giver charge 3 generates a hot, particle-rich and conical jet which strikes cartridge 7.

The particles 5 reflecting in the center tube 16 ignite the receiving shaft 17, which, because of its reaction, ignites the usual reinforcing shaft 20. The latter then ignites the free charge 22.

The described operation occurs both in the embodiment according to Fig. 2 and that according to Fig. 3.

For the successful tests, the following seams were used: 1. Giver sax: 45 wt% lead oxide 10 wt% potassium nitrate 15 45 wt% zirconium metal powder 3 wt% nitrocellulose

As already mentioned, the lead oxide serves as a lubricant in the gun barrel after reduction.

The potassium nitrate serves the purpose of safety during manufacture.

The zirconium metal powder acts as a fuel.

The nitrocellulose provides the function of a granulating binder.

2. Reception Sludge: 20.6 wt% zirconium metal powder 77.4 wt% Pb304 2 wt% vanadium pentoxide.

After mixing the powdery substances, 25% saturated nitrocellulose lacquer is added, as well as acetone for setting the desired consistency.

After the stirring, the lacquer can be applied and after drying it is fixed on it.

An advantage of this composition is the insensitivity to moisture, the mechanical insensitivity notwithstanding the high thermal sensitivity and the fixed connection with the carrier, namely the cartridge 7. The fixed connection is an important condition for the load-bearing capacity of the cartridge during transport and applying it to the weapon.

Pyrotechnic lacquers 40 which work in a similar manner can also be prepared from other fine-grained mixtures. _ * v. J '2 - * * 6 - such as, for example, as reducing agent boron / magnesium, titanium, silicon, phosphorus red or black, sulfur flour, antimony sulfide, zinc. Lead oxides, iron oxides, copper oxides are still suitable as oxidizing agents.

5 - The ignition system according to the invention consisting of a reciprocal pair of pyrotechnic sockets ensures ignition both at very short distances between the propellant charge igniter and the cartridge as well as at very large distances of more than 1 m, i.e.

10 that each cartridge 7 or each module reacts identically with respect to the ignition phase, independently of the charge density, the charge density corresponding to the number of modules in the charge space.

The only difference between a module mounted at the propellant charge cartridge 2 and a module fitted at the grenade 9 consists in the different time t = y ^ yaï Δχ * distance between two modules. V beam - velocity of the giver gases. The ignitability is independent of the prevailing pressure.

It is also important that the receiver shaft is insensitive to moisture and mechanical stress and adheres thereto.

According to Figs. 4 and 5, a combustible cartridge 13 is arranged in the cargo space 6 of a weapon block 5.

The cartridge 13 consists of a combustible material. It has a star-shaped cross section 110 of the center tube 16 with recesses 21, a wall surface 11 and the bores 18. The bores 18 are filled with the receiving shaft 17.

A jet 12 consists of hot and fast particles 14 and gases generated by the propellant charge cartridge 2 (not shown). These particles 14 and the gases radiate directly on the wall surface 11 of the center tube 16 and ignite the receiving shaft 17 at the 35 land thereon, so that it then ignites the propellant charge 22 via a reinforcing shaft 20.

According to Fig. 6, the cheeks 25 of a cartridge 24 extend in a star-shaped cross-section 26. Only the cross-section 26 is completely provided with a mass layer 17, which is therefore not applied to the cheeks 25.

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Bores 18 are also provided with the mass 17 therein.

According to Fig. 7, with a cartridge 27, the cheeks 28 are limited to a star-shaped cross section 29.

No bores 18 are provided in the region of the cross-section 29. In the cross-section 29, only 5 is the mass 17 corresponding to the length of the points 111.

According to Fig. 8, only a star-shaped cross-section 31 is present with a cartridge 30. No cheeks are applied. The mass 17 extends along the length 33 with a safety distance 32 against accidental ignition (cigarette test).

The beam 12, in addition to the circular cross-section defined by a circular drill 34 with the beam 35, also passes through the approximately triangular recesses 21. As a result, in the region C a considerably larger particle quantity of the beam 12 is achieved than this is achieved with a connecting circular center tube.

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Claims (10)

Ignition system for combustible cartridges with a propellant charge igniter on the weapon side and a reinforcement lock on the cartridge side, characterized in that the propellant igniter (2) has a transmitter 5 (3) and the cartridge (7) receiver shaft (17) for igniting the reinforcement shaft (20), the transmitter shaft (3) generating a hot, particle-rich and refreshing jet (12) and the receiving shaft (17) having a high input has sensitivity and therefore reacts very sensitively when the hot particles (30) get on it. Ignition system according to claim 1, characterized in that the receiving shaft (17) is arranged in bores (18) of a central tube (16) open on both sides. Ignition system according to claim 1, characterized in that the receiving shaft (17) is arranged on the inner wall (19) of the central tube (16) with the exception of edge parts (25). Ignition system with a giver axis and a receiver axis, characterized in that the giver axis (3) consists of 45% lead oxide, such as lead II oxide, lead IV oxide, lead menia, 10% by weight potassium nitrate, 42 wt% zirconium metal powder 3 wt% nitrocellulose. The donor gas according to claim 2, characterized in that it comprises the following ingredients: 25-90% lead oxide, 0-60% potassium nitrate, 20-80% zirconium metal powder, 0.25-8% nitrocellulose. Ignition system with a transducer axis and an Λ "/." \ 'I J}' J ~ i 'J ^ .... r -9-L · reception axis according to claim 1, characterized in that the receiving seal (17) has the following ingredients: 20.6 wt% zirconium metal powder, 77.4 wt% lead menia, 5. wt% vanadium pentoxide. Reception bag according to claim 4, characterized by the following components: 15-30 wt.% Metal powder, 60-80 wt.%, 5-10 wt.% Catalyst. An ignition system according to claim 2, characterized in that the center tube (16) has a star-shaped cross-section (110, 126, 129). Ignition system according to claim 2, characterized in that only the center tube (16), with the exception of the inserted cheeks (15), is provided with a low receiving shaft (17) with a high thermal response sensitivity. 10. Inflammatory system. according to claim 2, characterized in that only a length (111, 33) of the central tube (16) with a safety distance (32) is provided with the layer of receiving shaft (17) with high thermal response sensitivity. 3 r-ï ~ v, '' Λ -i 'J *' - · V