EP0275429A1 - Multichamber primer - Google Patents

Abstract

The invention relates to a propellant charge igniter which has at least two combustion chambers (7, 13) connected in series and separated from one another by throttle disks (8), in each of which an ignition mixture (6, 12) is accommodated, which differ from one another in terms of their combustion properties and thus have different combustion behavior. The combustion chamber volumes are matched to these ignition mixtures, so that the latter can burn off at the optimum pressure level for them.

Description

The invention relates to propellant charge igniters with a primary ignition element and with an ignition mixture which is arranged in a combustion chamber and is in the form of a molded body.

Propellant lighters are used to ignite propellant charges, in particular propellant powder beds. These propellant charge lighters are used, for example, in rockets, propellant cartridges or ejection charges or for pyrotechnic articles. In particular, however, they are used to ignite the propellant charge of ammunition for barrel weapons and are therefore referred to as propellant charge lighters.

In the case of propellant igniters of this type, the mechanically or electrically triggerable ignition element is spatially separated from a booster charge which, as a second mixture of substances, controls the actual ignition process, i.e. the ignition of the propellant powder.

Ignition mixtures of different shapes and compositions serve as reinforcing charges. These ignition mixtures can also be in the form of shaped bodies (ring tablets, disks, cylinders, etc.).

A propellant lighter should ignite a propellant powder bed as quickly and evenly as possible in the entire application temperature range with the lowest possible mechanical load.

The disadvantages of the known propellant charge lighter lie in non-uniformities in the flow rate of the igniting gases flowing out and the different outflowing times of the igniting gases.

It is known, for example, that when the ignition gases flow into the propellant powder bed at too high a rate, extinguishing processes can occur on the propellant powder surface. This leads to a more or less scattering ignition of the propellant powder bed.

The object of the present invention is to provide a propellant charge lighter which ensures improved ignition of the propellant powder bed.

This object is achieved by a propellant charge igniter with a primary ignition element and with an ignition mixture arranged as a shaped body in a combustion chamber, which is characterized in that at least two combustion chambers are provided, which are connected in series and separated from one another by a throttle disk and via this are in direct operative connection and that in each combustion chamber there is an ignition mixture which differs from the other ignition mixture (s) in terms of its combustion properties.

The propellant charge lighter according to the invention expediently has a cylindrical housing, one end of which is closed by a base piece in which the primary ignition element is accommodated.

A first combustion chamber, in which an ignition mixture is located, adjoins the base piece. This first combustion chamber is connected via a throttle disc to a second combustion chamber adjoining it, which also contains an ignition mixture.

The ignition mixtures are advantageously arranged in the central area of the combustion chambers.

The shape and the composition of the ignition mixtures are expediently chosen such that their combustion properties differ greatly from one another. The combustion chambers are expediently designed in such a way that they are optimally matched to the ignition mixtures contained therein.

This multi-chamber system ensures that the different ignition mixtures, which are known to require different combustion pressure levels, can burn off at the pressure levels that are optimal for them.

Due to the presence of at least two combustion chambers and different ignition mixtures attached therein, the optimal ignition conditions for a given propellant powder bed can be created. So it is possible to ensure an optimal mixing of the ignition gases, consisting of gas, condensates and hot particles. In addition, the flow rate of the ignition gases and the outflow time can be set.

To achieve this, the throttle disk is equipped with outflow bores in a preferred embodiment according to the invention. These outflow bores preferably have a different diameter. As a result and through the arrangement of these outflow bores, the outflow rate of the ignition vapor can be controlled in time.

According to a further preferred embodiment, the ignition mixtures are in the form of compacts. This makes it possible to give them a specific shape, which also enables the outflow speeds of the ignition vapor to be controlled over time.

The respective combustion chamber volume is preferably matched to the combustion properties of the ignition mixtures. This coordination is preferably achieved with compensation parts attached in the combustion chamber. These are inert inserts for the combustion chambers, with which both the distance of the ignition mixtures from the throttle plate (s) or bottom or end part as well as the combustion chamber volume can be changed.

The compensating parts are preferably ring-shaped spacers. The outer diameter of these spacers is preferably such that they abut the inner wall of the housing.

In a preferred embodiment, the ignition mixture present as a compact is held in the central region of the combustion chamber by a spacer (spacer) arranged above and below these ignition mixtures.

The last combustion chamber, i.e. the combustion chamber facing away from the ignition element is preferably provided with a closing part which is equipped with at least one outflow bore. The shape or the diameter of this outflow bore or the main outflow nozzle are also selected such that the ignition gases escape in the desired manner

In the manufacture of the propellant charge lighter according to the invention, the base piece, the compensating parts, the throttle plate and the end part are expediently produced in one piece using the cold extrusion process. This applies in particular to mass production.

• Figur 1 einen Längsschnitt durch einen erfindungs­gemäßen Treibladungsanzünder mit zwei Brennkammern;
• Figur 2 einen Längsschnitt durch einen erfindungs­gemäßen Treibladungsanzünder mit mehr als zwei Brennkammern;
• Figur 3 eine Aufsicht auf das Abschlußteil 14 der Fig. 1, und
• Figur 4 eine Draufsicht auf die in der Fig. 1 gezeigten Drosselscheibe 8.

The invention is explained in more detail with reference to FIGS. 1 to 4, which represent preferred embodiments: The figures show:

• 1 shows a longitudinal section through a propellant charge lighter according to the invention with two combustion chambers;
• FIG. 2 shows a longitudinal section through a propellant charge igniter according to the invention with more than two combustion chambers;
• Figure 3 is a plan view of the end part 14 of Fig. 1, and
• FIG. 4 shows a top view of the throttle disk 8 shown in FIG. 1.

The propellant lighter shown in FIG. 1 with two combustion chambers has a cylindrical housing 3, which is closed at the lower end by a disk-shaped base piece 1. In this bottom piece 1, a primary ignition element 2 is attached, which can be triggered either electrically or mechanically.
The first combustion chamber 7 is formed from the cylindrical housing 3, the base piece 1 and the throttle disc 8. The throttle disc 8 (see FIG. 4) has outflow bores 9. The size of the combustion chamber is set by the length and volume of the compensating parts 4, 5 and the thickness of the ignition mixture 6 present as a compact.

The adjoining second combustion chamber 13 is formed by the cylindrical housing 3, the throttle disc 8 and the end part 14, which has an outflow bore 15. The size of the second combustion chamber 13 is determined by the length and the volume of the compensating parts 10, 11 and the thickness of the ignition mixture 12 present as a compression body.

The compensating parts 4, 5, 10 and 11 are, in the embodiment shown in FIG. 1, annular spacers (spacers) which rest with their outer wall on the inner wall of the housing 3. The ignition mixtures 6, 12, which are in the form of compacts, are expediently disk-shaped and, with their outer diameter, also bear against the inner wall of the housing 3. These compacts are thus on the spacers and are held by them in the central region of the combustion chambers 7, 13.

The operation of this propellant lighter shown in Fig. 1 is as follows:

After either mechanical or electrical initiation of the primary ignition element 2, the resulting reaction products are blown into the combustion chamber 7 and ignite the ignition mixture 6 present as a compact.

If this ignition mixture consists of a nitrocellulose powder, then mainly hot gases are formed. The resulting gas pressure in the combustion chamber 7 is regulated by the size of the combustion chamber 7 and the choice of the outflow bores 9 of the throttle disk 8. The throttle disk 8 shown in FIG. 4 acts as a pressure-dependent valve through outflow bores 9 of different sizes. The large outflow bores throttle the combustion products of the ignition mixture 6 little, while the small outflow bores 9 block the more the higher the pressure in the combustion chamber 7 increases. By optimizing the diameter of the outflow bores 9 (for example several different bore diameters), a combustion pressure in the combustion chamber 7 which can be varied within wide limits and a regulated mass flow rate of the gases through the throttle disc can thus be achieved.

The combustion products of the ignition mixture 6 are introduced into the second combustion chamber 13 via the outflow bores 9 of the throttle disks shown in FIG. 4. These combustion products ignite the ignition mixture 12 present there as a compression body. This compression body can be, for example, a ring tablet made from black powder. In this case, the combustion products of the ignition mixture are mainly hot particles and condensates.

The optimal pressure level is set by the length of the compensating parts 10, 11 and the thickness of the ignition mixture compact 12. The hot gas products of the ignition mixture 6 mixed in the second combustion chamber 13 emerge together with the hot particle-condensate-gas mixture of the second ignition mixture 12 as a common ignition vapor through the outflow bore 15 of the connection part 14 shown in FIG. which is in a cartridge, for example.

The inventive propellant lighter shown in FIG. 2 with a plurality of combustion chambers also has a cylindrical housing 3 with a base piece 1 in which the electrically or mechanically triggerable primary ignition element 2 is attached. The first combustion chamber 19 is formed by the housing 3, the base piece 1 and the throttle disk 20 equipped with an outflow bore 21. The size of the combustion chamber is determined by the length and the volume of the compensating parts 16, 17 and the thickness of the ignition mixture compression body 18.

The further combustion chamber (s) 24 is (are) shown in simplified form in FIG. 2 and has (have) compensating parts 22, 23 and a throttle disk 25 with obliquely arranged outflow bores 26.

The last combustion chamber 30 of the multi-chamber system is formed by the throttle disk 25, the housing 3 and the end part 31 with the outflow holes 32. The size of this combustion chamber 30 is determined by the compensating parts 27, 28 and the ignition mixture compression body 29.

The compensating parts 16, 17, 22, 23, 27, 28 and the ignition mixtures 18, 29 in the form of compacts of the embodiment of the propellant charge lighter according to the invention shown in FIG. 2 are configured in the same way as the corresponding parts of the embodiment shown in FIG. it is ring-shaped spacers or compact discs. As in the embodiment shown in FIG. 1, the diameter of the throttle disks 20, 25 is such that their radial side surface abuts the inner wall of the cylindrical housing 3.

2 differs from that of FIG. 1 in that between the combustion chamber 19, which is adjacent to the ignition element 2, and the last combustion chamber 30, which is closed by the end part 31, one (or more) ) further combustion chamber (s) is (are) interposed. In this way it is possible to use differently shaped and composed ignition mixtures or compression molding compacts, so that the emerging ignition gases have the optimum temperature, speed etc. for the ignition of the propellant powder bed.

Reference symbol list

1 bottom piece
2 igniter
3 housing
4 compensation part
5 compensating part
6 Ignition mixture
7 1st combustion chamber
8 throttle plate
9 drain hole
10 compensating part
11 compensating part
12 Ignition mixture
13 2. Combustion chamber
14 final part
15 outlet bore
16 compensating part
17 compensating part
18 Ignition mixture
19 1st combustion chamber
20 throttle plate
21 drain hole
22 compensating part
23 compensating part
24 combustion chamber
25 throttle plate
26 drain hole
27 compensating part
29 Ignition mixture
29 Ignition mixture
30 combustion chamber
31 final part
32 Outflow hole

Claims (9)

1. propellant charge lighter with a primary ignition element and an ignition mixture which is arranged in a combustion chamber and is in the form of a shaped body,
characterized,
that at least two combustion chambers (7, 13, 19, 24, 30) are provided, which are connected in series and each separated by a throttle disc (8, 20, 25) and are in direct operative connection via this and
that in each combustion chamber (7, 13, 19, 24, 30) there is an ignition mixture (6, 12, 18, 29) which differs from the other ignition mixture (s) (6, 12, 18, 29) differs in terms of their combustion properties. 2. propellant charge lighter according to claim 1, characterized in that the throttle disc (8, 20, 25) has at least one outflow bore (9, 15, 21). 3. propellant lighter according to claim 2, characterized in that the throttle disc (8, 20, 25) has a plurality of outflow bores (9, 15, 21) of different diameters. 4. propellant lighter according to one of the preceding claims, characterized in that the respective volume of the combustion chambers (7, 13, 19, 24, 30) is matched to the combustion properties of the ignition mixtures (6, 12, 18, 29) attached therein. 5. propellant lighter according to claim 4, characterized in that for matching the volumes of the combustion chambers (7, 13, 19, 24, 30) compensating parts (4, 5, 10, 11, 16, 17, 22, 23, 28) in the Combustion chambers (7, 13, 19, 24, 30) are arranged. 6. propellant lighter according to claim 5, characterized in that the compensating parts (4, 5, 10, 11, 16, 17, 22, 23, 28) are designed as annular spacers. 7. propellant lighter according to one of the preceding claims, characterized in that the last combustion chamber (13, 30) has a closing part (14, 31) with at least one outflow bore (15, 32). 8. propellant lighter according to one of the preceding claims, characterized in that the ignition mixtures (6, 12, 18, 29) are present as a compact. 9. propellant lighter according to claim 8, characterized in that one or more ignition mixtures (6, 12, 18, 29) contain finely ground, inert material.

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