DE3523569A1 - Booster charge - Google Patents

Abstract

A booster charge for a detonating chain is proposed which, despite the use of damping or compensating material for compensating for longitudinal expansion of the explosive charge, makes possible a scarcely reduced output power and at the same time matching of the input sensitivity and of the output power.

Description

The invention relates to an amplifier charge which from an explosive charge placed in a housing stands, with a space between the explosive charge and a housing cover with damping material such as Example felt is filled.

Such amplifier charges are usually too together with transfer charges in an ignition chain turned around the mostly relatively small output terminals gie of a detonator especially with regard to the over significantly increase the footprint and duration to the less sensitive main explosive charge reliably initiate.

The booster charge consists of an explosive charge, which is designed to be due to its opposite the main charge higher sensitivity with less Print with shorter duration over a smaller area ini can be tiied and at the same time a shock Corresponding height with larger transmission area che and correspondingly longer pressure generated to the To ignite the main explosive charge properly.

Here it is from the literature (C.D. Hutchinson: "High-speed photographic experiments to investigate the effects of booster housing geometriy on the detonabili ty of secondary explosives ", R.A. R.D.E., Fort Hal stead, Sevenoaks, Kent, TN 14 7BP, England, 1984) be knows the case of the explosive charge on the ground with a Compensating material such as felt for inclusion  to prove the length of the explosive charge. Here However, the disadvantage of an unsafe and incomplete occurs constant detonation of the amplifier charge.

It is therefore an object of the invention to provide an amplifier to create charge, which despite an insert made of damping a safe and complete axial ini ti the amplifier charge enables and at the same time a variation in sensitivity and output level allowed.

This object is achieved in that the explosive charge in the form of at least two parts body is introduced into the housing, the diei gene parting surfaces of the partial body, which are parallel to The main axis of the housing runs without any space lie against each other, and that the partial body in the area of the ra arranged at certain intervals dialing partitions on each part of the parting surface cavities filled with damping material sen, the cavity parting surfaces - in the axial direction seen - without overlapping the entire cross Cover the cut surface of the explosive charge.

The amplifier charge advantageously consists of egg ner cylindrical explosive charge consisting of several cylindrical and / or annular partial bodies together inserts, the partial body from the same explosive are molded with different density.

An embodiment of the invention is in the drawing shown and will be described in more detail below ben. Show it  

Figure 1 is an amplifier charge, the explosive charge consists of two tiered partial bodies.

Fig. 2 is a similar amplifier charge from Teilkör cores with different density.

In Fig. 1 an example of the invention is shown a booster charge. The housing 3 of the United charge 1 contains a first partial body 2 a of the explosive, which is pressed to the bottom of the housing 3 . A central blind hole with axially extending side walls 4 a , 4 b is expediently introduced here. On the bottom 6 a of the blind hole and on the annular shoulders 6 b of the partial body 2 a , the damping material 8 is now consolidated. Subsequently, the second partial body 2 b , which is formed by itself, is pressed in such a way that small cavities 7 remain at the points at which the damping material 8 is located. Then the housing is closed with a lid 10 .

The damping layer is preferably applied symmetrically to the central plane of the explosive charge. This includes the advantage of a sufficiently long running distance of the shock wave initiation by the detonator 11 via the cover 10 to achieve a complete detonation build-up in the intensifying charge 1 . The damping layer is in any case a fault for the detonation build-up, but it is the running distances within the booster charge when attaching the divided damping layer in the central region of the explosive charge ge sufficiently long to achieve a full detonation effect at the output of the booster charge.

With direct contact of the explosive charge part body 2 a , 2 b along the axially extending separating surfaces 4 a , 4 b , a good transmission of the detonation wave is guaranteed despite the almost grazing incident detonation wave, without intermediate walls being present here. By introducing a divided damping layer 8 in the middle of the booster charge 1 , the input sensitivity is almost not reduced on the one hand, and on the other hand, the output power is affected much less than was the case with a previously known structure.

The division of the explosive charge into at least two partial bodies 2 a , 2 b , ( 2 c , 2 d) according to FIG. 2 leads to the possibility of using different types of explosive charge in the booster charge. These can be two or more different types. However, it is equally possible to use the same Sprengla granulate, with the first partial body 2 a being compressed to a higher degree. For the partial body 2 d in the vicinity of the detonator 11 , less compressed mate rial is used. This creates both a stronger output shock wave and a higher input sensitivity. An even finer differentiation is achieved if all sub-bodies 2 a , 2 b , 2 c , 2 d have different explosive densities. Then the sensitivity decreases from the input part under the middle part to the output of the booster charge and the shock wave pressure increases in the order mentioned.

The particular advantage of an amplifier according to the invention Kerladen can be seen in the fact that despite the use of damping material when building up the explosive charge  hardly reduced output power is achieved. Furthermore is depending on the selection and combination of the explosive charge materials an adjustment of the input sensitivity and the output power easily possible.

Claims (3)

1. booster charge, which consists of an explosive charge introduced into a housing, an intermediate space between the explosive charge and a housing cover being filled with damping material such as felt, characterized in that the explosive charge ( 2 ) in the form of at least two partial bodies ( 2 a , 2 b) is introduced into the housing ( 3 ), the parting surfaces ( 4 a , 4 b) of the partial bodies ( 2 a , 2 b) being parallel to the main axis ( 5 ) of the housing ( 3 ) run without any space between each other, and that the partial bodies ( 2 a , 2 b) in the region of the spaced apart spaced ra dialen partitions ( 6 a , 6 b) each on a part of the partitions ( 6 a , 6 b ) filled with damping material ( 7 ) te cavities ( 8 ), the cavity-separating surfaces ( 6 a , 6 b) - seen in the axial direction - cover the entire cross-sectional area of the explosive charge ( 2 a , 2 b) without overlap. 2. Booster charge according to claim 1, characterized in that the cylindrical explosive charge ( 2 a , 2 b) of the booster charge ( 1 ) from a plurality of cylindrical and / or ring-shaped part bodies ( 2 a , 2 b , 2 c , 2 d) exists. 3. amplifier charge according to claims 1 and 2, characterized in that the partial body ( 2 a , 2 b , 2 c , 2 d) of the explosive charge from the same chen explosives with different densities ( 9 a , 9 b , 9 c ) are shaped.