EP2090860A2 - Miniaturised ignition chain - Google Patents

Abstract

The miniaturized explosive train (12) has a detonator (10) and an ignition amplifier unit. The ignition amplifier unit has two ignition amplifiers which are modularly combined with one another according to power requirement at the output of the explosive train.

Description

The invention relates to a miniaturized ignition chain.

The invention has for its object to provide a miniaturized ignition chain, which can be varied depending on the power requirement at the output of the ignition chain and / or the allowable igniter Einschraublänge in the respective projectile (STANAG).

This object is achieved by the features of claim 1. For this purpose, the firing amplifier device of the firing chain has a first firing amplifier and a second firing amplifier which-depending on the power requirement at the output of the firing chain-are modularly combined with one another. At low power requirements, accordingly, only the first firing amplifier of the firing amplifier device is combined with the detonator of the firing chain formed by a miniature detonator. Preferred embodiments or further developments of the modular, miniaturized ignition chain according to the invention are characterized in the subclaims.

The modular, miniaturized ignition chain according to the invention has the advantage that it is possible, for example, by removing the second booster stage, ie the second booster, the high-explosive amplifier output for HE ammunition in an ignition amplifier output for igniting transfer charges of a cargo Reduce ammunition. At the same time, an adjustment of the detonator engagement length into the respective projectile takes place. Thus, it is possible in an advantageous manner, by unscrewing or removing the second booster stage, for example, to adapt a proximity fuse / multi-function fuse to the use as a time fuse.

The modularity is realized in such a way that the incoming booster stages are recorded in recordings that can be connected in a modular, positive or cohesive manner. The recordings can also be identical or identical to the respective booster housing. It may be provided that a booster is screwed or glued into a screw-in. This screw-in can then be screwed onto a thread of a receptacle or a housing of a previous booster stage.

Further details, features and advantages will become apparent from the following description of an embodiment of the inventive modular miniaturized ignition chain shown in the drawing or essential details thereof.

Show it:

Fig. 1

longitudinally sectioned on a larger scale an embodiment of the modular, miniaturized detonating chain,

Fig. 2

increases an embodiment of the miniature detonator of the ignition chain according to Fig. 1 in a longitudinal section,

Fig. 3

longitudinally sectioned an embodiment of an insensitive first booster, ie a first firing amplifier, which forms a second stage of the modular miniaturized firing chain, the first stage of which from the miniature detonator according to Fig. 2 is formed,

Fig. 4

a longitudinal sectional view of a second booster stage, ie a second booster amplifier, the first of the booster Fig. 3 is drawn at a distance, and

Fig. 5

a longitudinal sectional view of the booster, ie the first and second firing amplifier according to the FIGS. 3 and 4 that - as in Fig. 1 combined with each other.

Fig. 1 illustrates an embodiment of the modular, miniaturized firing chain with a miniature detonator 10 and an associated detonating chain 12, wherein respect Further details of the miniature detonator 10 and the ignition chain 12 to the following description of FIGS. 2 to 5 Reference is made.

Fig. 2 illustrates enlarged a miniature detonator 10, which is provided for over ignition on a firing chain 12. How out Fig. 2 can be seen, the miniature detonator 10 has a charge 14 small mass of, for example. 10 to 20 mg. The charge 14 is provided for the directed generation of its output from a centric initiation site 16 to a detonator bottom 18. The detonator bottom 18 is formed concaved for forming in a flat disc (flyer) 20 high speed. The Flyer 20 is in Fig. 2 from the miniature detonator 10 axially spaced slightly indicated by thin dashed lines.

The charge 14 of the miniature detonator 10 has a primary charge 22 and a secondary charge 24 adjacent thereto. The primary charge 22 is provided in a centering element 26. The secondary charge 24 adjoins the concavely dented detonator bottom 18.

To initiate the primary charge 22, the miniature detonator 10 has an electrical bridge element 28. The electric bridge element 28 is provided on an electrically insulating bottom termination element 30 of the miniature detonator 10. Extending out of the electrically insulating bottom termination element 30 are connecting elements 32 which are in contact with the electrical bridge element 28 and are spaced apart from one another.

The electrically insulating bottom termination element 30 has a peripheral sleeve 34 which encloses the bottom termination element 30.

The centering element 26 is attached to an extension sleeve 36. Between the extension sleeve 36 of the centering element 26 and the peripheral sleeve 34 of the electrically insulating bottom termination element 30 is in the in Fig.2 drawn embodiment of the miniature detonator 10 a compensating sleeve 38 is provided.

The concavely dented Detonatorboden 18 is materialeinstückig formed with a detonator shell 40. The detonator shell 40, the extension sleeve 36 of the centering element 26, the compensating sleeve 38 between the extension sleeve 36 and the peripheral sleeve 34 of the bottom end element 30 and the peripheral sleeve 34 are welded tightly to one another at the connection side remote from the concavely dented detonator bottom 18. This tight welding is designated by the reference numeral 42.

The miniature detonator 10 according to Fig. 2 forms a first stage of the miniaturized, modular ignition chain, the second stage of which is formed by an insensitive first booster 54 or by a first booster amplifier (see FIGS Figures 3 and 5 ). The insensitive first booster 54 has an input diameter that matches the output diameter of the miniature detonator 10. The first booster 54 has an insensitive explosive charge 56, which is provided in a funnel-shaped widening receiving space 58 of a first booster housing 60. The funnel-shaped enlarged receiving space 58 in the first booster housing 60 is closed on the side facing the miniature detonator with a closing element 62 and on the other side facing away from it by a closing element 64 (see FIGS Figures 3 and 5 ).

The insensitive first booster 54 can be combined or combined with a second booster stage 66, which in Fig. 4 from the first booster 54 according to FIG Fig. 3 axially spaced and in Fig. 5 is shown combined with the first booster 54.

The two booster stages can be arranged spaced apart depending on the structural conditions in the igniter.

The second booster stage 66 has an associated second booster housing 68 which is formed with a likewise funnel-shaped widening receiving space 70. In the receiving space 70, an explosive charge 72 is provided. The receiving space 70 of the second booster housing 68 of the second booster stage 68 is at the first booster 54 (see Fig. 3 ) facing side by means of a closing element 74 and on the side facing away from the second side closed by a closing element 76.

The end element 64 of the first booster 54 may be concave-dented to form a flyer. Is in Figure 3 illustrated by an arcuate, dashed line 78. Likewise, it is possible for the end element 76 of the second booster stage 66 to be concave-dented to form a flyer. Is in Fig. 4 illustrated by the dashed line 80.

As already mentioned, the figures illustrate a miniaturized modular firing chain in which the first booster 54, i. H. the first boost amplifier, and the second booster stage 66, d. H. the second firing amplifier, each forming independent components that are arranged adjacent to each other or arranged. For this purpose, it is possible to connect these positive, cohesive or materially together. Easily detachable connections are to be preferred, since this often allows a simpler, faster adaptation to the intended use. Especially screwed into consideration, since they provide sufficient stability or leadership, such as via a corresponding thread or bore in conjunction with a locking ring, while also easily be solved again. However, clamp connections, rivet connections, jaw couplings, adhesive layers and the like can also be used.

The miniature detonator 10 may, for. B. have a diameter of 2.5 mm and an axial length dimension of 3.5 mm. It is understood that other dimensions are possible.

The explosive charge of the miniature detonator is, for example, 10 to 20 mg, without being limited thereto.

List of reference numerals:

10

Miniature Detonator (for 12)

12

ignition chain

14

Charge (out of 10)

16

Centric initiation location (from 14)

18

Detonator floor (from 10)

20

Flat Disc (Flyer) (out of 18)

22

Primary charge (out of 14)

24

Secondary charge (out of 14)

26

Centering element (from 10 to 22)

28

Electric bridge element (for 22 to 30)

30

Electrically insulating bottom termination element (from 10 to 28)

32

Connection elements (for 28)

34

Circumferential sleeve (from 30)

36

Extension sleeve (from 26)

38

Compensating sleeve (between 34 and 36)

40

Detonator Mantle (from 10 for 18)

54

First booster / first booster (out of 12)

56

Insensitive explosive charge (from 54)

58

Funnel-shaped extended receiving space (in 60 for 56)

60

First booster housing (from 54)

62

First closing element (from 54)

64

Second closing element (from 54)

66

Second booster stage / second booster (from 12)

68

Second booster housing (from 66)

70

Recording room (in 68 for 72)

72

Explosive charge (in 70)

74

First closing element (from 70)

76

Second final element (out of 70)

78

Arched dotted line (at 64)

80

Arched dotted line (at 76)

Claims (15)

Miniaturized firing chain, with a detonator and a firing amplifier device,
in which
the firing amplifier device has a first firing amplifier (54) and a second firing amplifier (66) which, depending on the power requirement at the output of the firing chain, can be modularly combined with one another. Ignition chain according to claim 1,
in which
the miniature detonator (10) has a charge (14) with a small mass and is designed to generate its power from a centric initiation site (16) in a direction toward a detonator bottom (18) for forming into a flat disc (Flyer) (20) high speed concave dented is formed. Ignition chain according to claim 2,
in which
the charge (14) has a primary charge (22) and a secondary charge (24) adjacent thereto, the primary charge (22) being provided in a centering element (26) of the miniature detonator (10) and the secondary charge (24) being concave dented detonator bottom (18) adjacent. Ignition chain according to claim 3,
in which
for initiating the primary charge (22) an electrical bridge element (28) is provided, wherein
the electrical bridge element (28) is provided, in particular, on an electrically insulating bottom termination element (30) of the miniature detonator (10), wherein connection elements (32) contacted with the bridge element (28) extend out of the bottom termination element (30). Ignition chain according to claim 4,
in which
the electrically insulating bottom termination element (30) has a peripheral sleeve (34). Ignition chain according to one of claims 3 to 4,
in which
the centering element (26) is attached to an extension sleeve (36). Ignition chain according to claims 5 and 6,
in which
between the peripheral sleeve (34) of the electrically insulating bottom closure element (30) and the extension sleeve (36) of the centering element (26) a compensating sleeve (38) is provided. Ignition chain according to one of claims 2 to 7,
in which
the concavely dented detonator bottom (18) is integral with a detonator shell (40). Ignition chain according to claim 8,
in which
the detonator jacket (40), the extension sleeve (36) of the centering element (26), the compensating sleeve (38) and the peripheral sleeve (34) of the electrically insulating bottom termination element (30) are tightly welded together at the connection side facing away from the concavely dented detonator bottom (18) , Ignition chain according to one of claims 2 to 9,
in which
the miniature detonator (10) forms a first stage of a miniature ignition chain, the second stage of which is formed by an insensitive first booster (54). Ignition chain according to claim 10,
in which
the insensitive first booster (54) has an input diameter that matches the output diameter of the miniature detonator (10). Ignition chain according to claim 10 or 11,
in which
the first booster (54) has an insensitive explosive charge (56) which is provided in a funnel-shaped widening receiving space (58) of a first booster housing (60). Ignition chain according to one of claims 10 to 12,
in which
the insensitive first booster (54) can be combined or combined with a likewise second funnel-shaped booster stage (66), wherein the second booster stage (66) is provided in particular in an associated second booster housing (68) which is connected to the first booster housing (60). borders. Ignition chain according to claim 12,
in which
the first booster housing (60) is designed to form a flyer with a concaved floor. Ignition chain according to claim 13,
in which
the second booster stage (66) is designed to form a flyer with a concavely dented bottom.

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