EP0111198A2 - Percussion fuze - Google Patents

Abstract

1. Percussion fuse with a priming cap (14) which can be pierced from the rear by a percussion needle (18), with blocking bodies (29) which, in their blocking position, on the one hand, are located in a recess (28) in the percussion needle (18) and on the other hand rest against a pin (21) fastened in the fuse casing (10) and against a displaceable inertia sleeve (19), in order to retain the percussion needle (18), and with a spring (24) which at one end is supported on the inertia sleeve (19) and endeavours to hold the inertia sleeve (19) in its rearmost position, characterized in that the spring (24) is supported at its other end on the fuse casing (10), and in that, to shift the percussion needle (18) towards the priming cap (14), only the force of inertia is exerted on the percussion needle (18).

Description

The invention relates to an impact detonator, with an ignition capsule which can be pierced from behind by an ignition pin, with locking bodies which are in their locking position on the one hand in a recess in the ignition pin and on the other hand rest on a bolt fastened in the ignition housing and on a displaceable inertia sleeve, to hold the firing pin and with a spring, which is supported with its rear end on the inertial sleeve and tends to hold the inertial sleeve in its rearmost position.

In a known impact detonator of this type (see CH-PS 623408), a mechanical delay device is provided so that the projectile can penetrate as deep as possible into the target.

In another known impact detonator of this type (see CH-PS 352 598), a device for delayed ignition is provided in addition to a momentary detonator, with an inertial ignition pin which is supported directly by a weak flight safety spring and is held in its initial position during the flight. In this known detonator there is a risk that the delay when the projectile penetrates into soft earth or snow, i.e. Braking of the projectile is initially so small that the inertial firing pin hits the primer at too low a piercing speed and is therefore unable to ignite it properly.

The object that is to be achieved with the present invention is now to create a detonator in which the ignition pin retracts as long as the projectile penetrates into soft earth or snow will hold until the bullet has penetrated harder ground. The delay in the projectile, ie its deceleration, is then so great that when the firing pin is released, it hits the primer at a sufficiently high piercing speed to ensure proper ignition.

The invention also aims to provide a detonator that can be destroyed relatively safely if the detonator has not responded and the projectile has become a dud.

This object is achieved according to the invention in that the spring is supported with its other end on the igniter housing and that only the inertial force acts on the ignition pin to move the ignition pin against the ignition capsule.

Compared to the known inertial response system, the detonator according to the invention differs in that it uses a much stronger flight safety spring. This stronger spring means that if the primer capsule is not correctly pierced (unexploded ordnance), the firing pin is more likely to be pushed back and re-piercing, e.g. is practically avoided by clumsy handling of the dud.

The inertial piercing system according to the invention can be used both with an instantaneous capsule as a "double igniter", e.g. with additional ignition delay, as well as with a delay primer. In the latter case, the detonator is provided with a device which makes it possible to lock the instantaneous impact system.

• Fig. 1 einen Längsschnitt durch den Aufschlagzünder vor dem Abschuss des Geschosses,
• Fig. 2 denselben Längsschnitt durch den Aufschlagzünder gemäss Fig.1, während der Verzögerung im Ziel,
• Fig. 3 denselben Längsschnitt durch den Aufschlagzünder gemäss Fig.l, beim Anstechen der Zündkapsel.

An embodiment of the impact detonator according to the invention is described in detail below with reference to the accompanying drawing. It shows:

• 1 shows a longitudinal section through the impact detonator before the projectile is fired,
• 2 shows the same longitudinal section through the impact detonator according to FIG. 1, during the deceleration in the target,
• Fig. 3 the same longitudinal section through the impact detonator according to Fig.l, when piercing the primer.

The impact detonator according to the invention has a housing 10 with a bore 11 and a channel 12. In the channel 12, a slide 13 is slidably mounted. According to FIGS. 2 and 3, this carriage 13 contains a primer 14. The primer 14 consists in the usual way of a prick-sensitive primer 15, which is located in a capsule housing 16. This capsule housing 16 has an opening 17 at the bottom through which an ignition pin 18 can pierce the ignition compound 15.

The carriage 13 can be moved from a safety position, in which the primer 14 is not in the area of the firing pin 18, to an arming position, in which the primer 14 is located in the area of the firing pin 18. In Fig.l. is the safety position and in Fig. 2 and 3 the focus is shown. In the mentioned bore 11 of the housing 10, a sleeve 19 is slidably mounted. According to Fig.l this sleeve 19 abuts in the safety position of the carriage 13 with its front end against this carriage 13 and with its rear end against a flange 20 of a bolt 21. This flange 20 is on the one hand against a shoulder 22 of the bore 11 and is on the other hand held by a flange 23 in the bore 11. The sleeve 19 is thus secured against any displacement in the safety position of the slide 13. However, as soon as the carriage 13 is in its focused position, the sleeve 19 can be pushed forward against the force of a strong spring 24, as can be seen from FIGS. 2 and 3. In this foremost position of the sleeve 19, a shoulder 25 of the sleeve 19 bears against a ring 26 which is fastened in the housing 10 of the impact detonator. In this sleeve 19, the ignition pin 18 is slidably mounted. At the rear end of the firing pin 18 there is a longitudinal bore 27 and a transverse bore 28. The aforementioned bolt 21 projects into the longitudinal bore 27 of the ignition pin 18 and there are two spherical locking bodies 29 on both sides of the bolt 21 in the transverse bore 28. As can be seen from FIG. 1, these two locking bodies 29 lie on an annular shoulder 30 of the sleeve 19 and thereby secure the firing pin 18 against a forward shift. In the position according to FIG. 1, the firing pin 18 also bumps against the flange 20 of the bolt 21 with its rear end and therefore cannot move backwards either.

The firing pin 18 has an annular shoulder 31 in the central region, which interacts with a corresponding annular shoulder 32 in the interior of the sleeve 19. As can be seen from FIG. 3, the shoulder 31 of the ignition pin 18 abuts against the shoulder 32 inside the sleeve 19 as soon as the tip of the ignition pin 18 penetrates into the ignition capsule 14.

• Der beschriebene Zünder befindet sich im Kopfteil eines Geschosses. Beim Abschuss des Geschosses wird der Schlitten 13 durch den Drall oder durch eine Feder au-s seiner Sicherheitsstellung gemäss Fig. 1 in seine Scharfstellung gemäss Fig. 2 und 3 bewegt. Während sich das Geschoss in der Luft befindet und sein Ziel noch nicht erreicht hat, wird durch die relativ starke Feder 24 die Hülse 19 in ihrer hintersten Stellung gehalten. Durch den Bolzen 21 werden die Sperrkörper 29, die sich in der Querbohrung 28 des Zündstiftes 18 befinden, gegen die ringförmige Schulter 30 der Hülse 19 gedrückt und verhindern, dass sich der Zündstift 18 nach vorne bewegt. Solange die Hülse 19 unter der Kraft der Feder 24 sich in ihrer hintersten Stellung befindet (Fig.l), ist auch der Zündstift gegen jede Verschiebung nach vorne oder nach hinten gesichert. Beim Eindringen des Geschosses in ein Ziel wird das Geschoss verzögert. Erst wenn die Verzögerung einen gewissen Wert erreicht hat, bewegt sich die Hülse 19 infolge ihrer Trägheit entgegen der Kraft der Feder 24 nach vorne, wobei diese Bewegung von der Stärke der Feder 24 abhängt. Je stärker die Kraft der Feder 24, desto grösser muss die Verzögerung des Geschosses sein, damit sich die Hülse 19 nach vorne bewegen kann. Beim Eindringen des Geschosses in ein Ziel wird die Verzögerung des Geschosses auf einen Wert ansteigen der ausreicht, dass sich unter der Trägheit der Hülse 19 die Feder 24 zu komprimieren beginnt. Die Hülse 19 wird dadurch nach vorne geschoben. Die Trägheit des Zündstiftes 18 bewirkt, dass die Sperrkörper 29 an der Schulter 30 der Hülse 19 anliegen und sich sowohl die Hülse 19, als auch der Zündstift 18 mit den Sperrkörpern 29 nach vorne bewegen. Sobald die Sperrkörper 29 sich nicht mehr im Bereiche des Bolzens 21 befinden, werden sie von der Schulter 30 der Hülse 19 radial nach innen gedrückt. Dies hat zur Folge, dass sich jetzt der Zündstift relativ zur Hülse 19 nach vorne bewegen kann, bis durch die Spitze des Zündstiftes die Zündkapsel 14 angestochen werden kann.

The impact detonator described works as follows:

• The detonator described is located in the head part of a projectile. When the projectile is fired, the slide 13 is moved by the twist or by a spring from its safety position according to FIG. 1 into its armed position according to FIGS. 2 and 3. While the projectile is in the air and has not yet reached its target, the sleeve 19 is held in its rearmost position by the relatively strong spring 24. By means of the bolt 21, the locking bodies 29, which are located in the transverse bore 28 of the ignition pin 18, are pressed against the annular shoulder 30 of the sleeve 19 and prevent the ignition pin 18 from moving forward. As long as the sleeve 19 is under the force of the spring 24 in its rearmost position (Fig.l), the firing pin is secured against any displacement forwards or backwards. The bullet is decelerated when the bullet enters a target. Only when the deceleration has reached a certain value does the sleeve 19 move forward due to its inertia against the force of the spring 24, this movement being dependent on the strength of the spring 24. The stronger the force of the spring 24, the greater the delay of the projectile must be so that the sleeve 19 can move forward. When the bullet enters a target, the bullet's deceleration will increase to a level sufficient to be below the inertia of the sleeve 19, the spring 24 begins to compress. The sleeve 19 is thereby pushed forward. The inertia of the firing pin 18 causes the locking bodies 29 to bear against the shoulder 30 of the sleeve 19 and both the sleeve 19 and the firing pin 18 with the locking bodies 29 move forward. As soon as the blocking bodies 29 are no longer in the region of the bolt 21, they are pressed radially inward by the shoulder 30 of the sleeve 19. The consequence of this is that the firing pin can now move forward relative to the sleeve 19 until the priming capsule 14 can be pierced through the tip of the firing pin.

If for some reason the primer 14 has not been fired, when the delay disappears, the spring 24 is able to push the sleeve 19 back to its original position as shown in FIG. 3, the sleeve 19 is pushed back by the amount a. Since the shoulder 31 of the ignition pin 18 rests on the shoulder 32 of the sleeve 19 (FIG. 3), the ignition pin 18 is also pushed back by the amount a. Thus, after the impact delay has disappeared, the firing pin 18 can no longer pierce the squib 14. Since the impact deceleration is relatively large, a correspondingly strong spring 24 can be used. If, therefore, the firing pin 18 is no longer secured against displacement by the locking body 29, as shown in FIG. 1, the firing pin 18 is still secured by the relatively strong spring 24 - after an ignition failure - against undesired puncturing of the primer 14 .

Claims (7)

1. impact detonator with an ignition capsule (14) which can be pierced from the rear by an ignition pin (18), with locking bodies (29) which are in their locking position on the one hand in a recess (28) of the ignition pin (18) and on the other a bolt (21) fastened in the igniter housing (10) and against a displaceable inertia sleeve (19) in order to hold the ignition pin (18) in place, and with a spring (24) which is supported on the one hand on the inertia sleeve (19) and has the endeavor to keep the inertia sleeve (19) in its rearmost position, characterized in that the spring (24) is supported on the igniter housing (10) on the other hand, and that only the inertia force on the ignition pin is used to move the ignition pin (18) against the ignition capsule (14) (18) attacks. 2. impact detonator according to claim 1, characterized in that the ignition pin (18) has a shoulder (31) which cooperates with a shoulder (32) on the inside of the inertia sleeve (19) to counter the advance of the ignition pin (18) to prevent the squib (14) if the inertia sleeve (19) is not in its foremost position. 3. impact detonator according to claim 1, characterized in that the inertia sleeve (19) has on its inside a second shoulder (30) on which the blocking body (29) is supported in its blocking position and that the bolt (10) fastened in the detonator housing (10) 21) has a smooth, cylindrical surface so that the inertial sleeve (19) and the ignition pin (18) move together under the effect of inertia. 4. impact detonator according to claim 1, characterized in that a transversely to the ignition pin (18), the squib (14) containing slide (13), which can be moved from a safety position to a focus, in its safety position a displacement of the inertial sleeve (19 ) and the ignition pin (18) prevented. 5. impact detonator according to claim 1, characterized in that the inertia sleeve (19) has on its outside a shoulder (25) which in the foremost position of the inertia sleeve (19) abuts a stationary ring (26) of the detonator housing (10). 6. impact detonator according to claim 1, characterized in that the primer (14) is designed as a pyrotechnic delay primer. 7. impact detonator according to claim 1, characterized in that only the inertial force of the ignition pin (18) acts.

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