CH628979A5 - Projectile impact fuze - Google Patents

Description

628979

2nd

PATENT CLAIM Bullet detonator with a detonator housing, the one-piece front end wall of which is located in front of a recess for an impact plunger lying against the inside of the end wall and closes it, which plunger is displaced axially backwards from the end wall deformed on impact and triggers the detonation of the projectile that the end wall (6) is made in one piece with the casing part of the igniter housing (1) and has a central nose part (8) which, via a ring part (7) of small axial wall thickness (t) forming a predetermined breaking point, with the material of the casing part in Connection is established, the wall thickness of the said ring part (7) being determined by an annular groove (10, II) concentric with the axis of the igniter housing (1).

The present invention relates to a projectile detonator according to the preamble of the claim.

Impact fuses are known in which the end wall consists of a separately produced cover, a so-called membrane, which is inserted into an annular groove in the front recess of the cylinder housing. Such impact detonators are expensive because, on the one hand, in addition to the cylinder housing, a membrane has to be produced and inserted into the cylinder housing and secured there.

In addition to this design, according to CH-A 377 232, an impact detonator has also become known, in which the end face is connected in one piece to the casing part of the projectile housing and the casing part is designed as a desired deformation point. The impact ram in the recess behind the end wall is thus pushed backward through the shortening of the fuse housing caused by the deformation. The deformation of the ignition housing and thus the displacement of the impact tappet takes place through a combination of individual deformations, so that safe working cannot be ensured. In addition, the front wall must be dimensioned precisely so that it can react to very small impact forces on the one hand, and on the other hand it is not already deformed by external influences such as rain and snow or hail and the detonation is triggered before the target.

It is therefore an object of the invention to design the end wall as part of the detonator housing and to strike the impact plunger directly from the end wall without additional deformation of parts of the detonator housing.

According to the invention this is achieved according to the features in the characterizing part of the patent claim.

Since the end wall is an integral part of the igniter housing, the igniter housing can be finished on the lathe. The structure is therefore simpler and therefore much cheaper to manufacture. At the same time, it is also ensured that the cavity in the front part of the igniter housing is hermetically sealed to the front.

With the impact detonator according to the invention, it is also possible to adjust the resistance to the nasal part being pressed into the detonator housing by giving the thin ring part of the wall dimensions such that this thin ring part reliably protects against rain and the like during the flight, but certainly breaks when the nose part hits the ground or a target on the ground.

Two preferred embodiments of the invention are explained in more detail below with reference to the attached drawing.

The drawing shows:

Fig. 1 shows a longitudinal section through part of an impact detonator according to the invention and

Fig. 2 shows a modified embodiment of Fig. 1 in the same representation.

The impact igniter, of which the front parts are shown in the drawings, consists of an igniter housing 1 with a cylindrical recess 2, in which an axially displaceable impact tappet 3 is located. In a manner known per se, the impact tappet 3 can be formed at its front end to form a stop plate 4, the diameter of which is somewhat smaller than the diameter of the recess 2. The impact tappet 3 has a flat, radially oriented surface 5 at its front end which absorbs the impact energy picks up when the projectile hits.

Immediately in front of the surface 5 in a parallel orientation there is an end wall 6 on the jacket part of the igniter housing, which closes the recess 2. According to the present invention, this end wall 6 is an integral part of the igniter housing 1, with which it is connected via a ring part 7 which is thin in the axial direction. This ring part 7 is located in front of the surface 5 of the impact ram 3. The middle part of the end wall 6 is designed as a nose part 8, which projects from the end wall 6 as far as the front edge 9 of the detonator housing. This is shown in Fig. 1.

The ring part 7 designed, for example, according to FIG. 1 can be produced by screwing in a groove 10 from the front of the igniter housing. The ring part 7 is then in principle a destructible membrane with a predetermined breaking point on the inner groove edge (location of the greatest concentration of forces). The nose part 8 touches the target during the impact of the projectile, in order then to transmit the impact energy to the end wall 6, so that there is a break at the predetermined breaking point.

The thickness of the end wall 6 depends on the dimensions of the ring part 7, the breaking load decreasing when the thickness dimension t is reduced and the diameter d of the nose part 8 is reduced increase or decrease the size of the detonator to meet any requirements that are desired for certain projectiles, so that in all cases a break occurs only upon impact of the projectile, but not during flight.

1 gives very good protection against damage during transport and handling due to the outer ring shoulder 9.

In the embodiment according to FIG. 2, the detonator housing has a hemispherical shape at the front end. A circumferential groove 11 which is pierced in the radial direction and which is perpendicular to the ignition axis ensures that the ring part 7 is given the desired thickness ti and that the remaining part of the material forms the nose part 8 with the predetermined diameter di. Provided that the impact occurs directly from the front and towards the center of the nose part, the nose part shears off along the diameter di at a breaking load which is selected to be approximately as large as in the embodiment according to FIG. 1. The nose part 8 and thus the Impact tappets 3 are then moved back on impact as far as the axial depth of the groove 11 corresponds.

In practice, however, an igniter arrangement according to FIG. 2 shows greater sensitivity since it is also able to work in the event of an oblique impact. Even if the impact is made so that there is a point on the side of the nose part 8

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is hit, this part absorbs the impact forces in order to then forward them to the ring part 7.

On the other hand, however, the training according to FIG. 2 requires greater caution and greater protection against damage during transport and handling. Such protection can be provided by inserting a safety transport clip into the groove 1, which has the shape of a plate or fork, the thickness of which corresponds to the axial dimension of the groove 11.

The invention is not limited to the two illustrated embodiments and can be modified within the scope of the skilled person without departing from the scope of the invention. So you can alternatively design the thin ring part on the lathe so that the groove, viewed from the front, extends at an angle of, for example, 45 °. The shape of the turning steel and the depth of the groove are then selected so that the remaining material is given the desired strength. The predetermined breaking point can also be produced by producing a groove io directed forward in the interior of the ignition housing on the inside of the end wall 6, which can be done together with the drilling out of the recess 2. In this way, the nose of the detonator receives a continuous, uninterrupted outer surface.

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1 sheet of drawings