CZ279062B6 - training cartridge shell - Google Patents

Abstract

A training cartridge shell, particularly for small and medium calibre weapons, with autodestruct system, formed by two independent, physically differentiated initiation systems (13, 20), the first using mechanical inertia and the second heat.<IMAGE>

Description

Technical field

The invention relates to a projectile projectile bullet, in particular for small and medium calibers, formed by a body within which a tracer is developed in the rear, a explosive in the middle and a lighter in the front.

BACKGROUND OF THE INVENTION

Small and medium caliber practice missiles are used in practice shooting in confined, endangered space. Known designs of these missiles usually use two methods of solution. The first is characterized by classical shooting, where instead of explosive is used another substitute explosive mass.

The disadvantage of this solution is the possibility of inadmissible crossing of the defined danger area during the practice shooting, because during the impact there is a reflection from the terrain and the bounce of the missile outside this space, or its crossing at a larger angle of elevation.

In the second solution there is an explosive charge in the projectile, which is initiated by means of one initiation system. This initiation system is typically connected to the lighter.

The disadvantage of this solution is a significant percentage of failures, when the self-destruction of the missile is not performed.

This reduces the safety after the shot, when the unexploded projectile behind the target area gets out of the defined area.

SUMMARY OF THE INVENTION

The aforementioned disadvantages are greatly reduced by the practice charge missile of the invention, whose self-destruct system is formed by two independent, physically different initiation systems, the first initiation system being the mechanical inertia and the second thermal.

The application of this self-destruct system increases the reliability of the missile self-destruct function, since both systems are completely independent of each other. Another advantage is that the independent initiator systems each operate on a different physical principle. One is based on the inertia of the mass when imparting kinetic energy to the projectile and the other on the ignition capability of heat transfer.

In the barrel development, both activated independent initiation systems simultaneously provide barrel and mask security.

Overview of figures in the drawing

The projectile bullet of the invention is shown in the basic embodiment in longitudinal section with a partial view in its front ogival portion.

-1GB 279062 B6

DETAILED DESCRIPTION OF THE INVENTION

The projectile bullet is formed by a body 1, the inner space of which is divided by a transverse partition 2. Externally, the bullet body 1 is equipped with a guide ring 2 · In the rear part of the interior space missiles in place of partition 2 is inserted circular cup 4 At least one spacer 5 is placed on the cup 4 with an opening at the cup boss 4. A cardboard tube 2 is inserted at the rear of the bullet compartment at the rear of the bullet compartment. The shank 7 is pressed into the remaining space. an opening filled with a cup 4 with fine-grained dust 8. On the other hand, the partition 2 is provided with a further spacer 5 with a central through hole over which the rear detonator 2 is located. is to the body by 1 screw connection m connected lighter 11, externally closing its bulky body 1 missile. In the lighter 11, a sleeve 12 with a stab mechanical mechanical inertia system 13 is mounted by screw connection. then, by another channel (not shown), connected via a fuse 18 to the front detonator 19. The fuse 18 with the front detonator 19 constituting the detonator is screwed into the lighter 11 so that in the assembled assembly the front detonator 19 engages the front explosive ZLO. The clearance between the lighter 11 and the explosive 10 is delimited by a spacer 5 at the detonator site.

The stem 7 with the cup 4, the fine-grained dust 2 in the cup cavity 4 and the through opening of the partition 2 together with the rear detonator 2 form a thermal initiation system 20.

When the wound develops in the barrel (not shown), both independent initiation systems 12, 22 are activated. The kinetic energy of the projectile causes inertia forces in the mechanical inertia system 12 where the igniter 16 overcomes the resistance of the coil spring 15 and punctures the needle. 14 ,. Activation of the igniter 2 causes the flame to be whipped by a channel (not shown) onto the delay component 17. The delay component 17 can be shaped according to the internal arrangement of the lighter 11 into a number of shaped elements. The delay time is chosen within a certain range taking into account the parameters of the weapon and the size of the threatened area. After the burn-up of the delaying composition 17, terminated by the elevation composition (not shown), the flame on the front detonator 19 is blasted (not shown) and the projectile self-destructs as a result of initiation of the explosive 10. During the development of the wound in the barrel (not shown), the whip channel (not shown) to the front detonator 19 is closed for a short time before the barrel is moved in the barrel and close to the barrel. The closure is achieved by a detonator. This achieves the barrel and in part also mask certainty.

During the development of the wound in the barrel (not shown), the ignition component of the tracer 7 is ignited. The tracer 7 gradually burns on the flight path

The flask is disposed approximately in parallel layers until the burning layer is transferred to the cup 8. A portable component of the fine-grained dust 8 is located in the concave of the cup 8 and the through hole of the septum 2 as a result of the heat transfer from the stem 7 to the cup 8. The flame is directed to the rear detonator 9. The function of the rear detonator 9 initiates the explosive 10 and thereby self-destructs the missile through the thermal initiation system 20. Preferably, different timing of the two above-mentioned independent initiation systems 38, 20 can be used.

Industrial applicability

The technical solution according to the invention is advantageous in particular for training cartridges. The two initiation systems 43, 20 are completely independent of each other and operate on a different physical principle. Both serve to initiate one common explosive 10 in one missile and thus complement each other advantageously.

The result is a higher reliability of function than in the known embodiments.

Claims (2)

PATENT CLAIMS 1. A projectile bullet, in particular for small and medium calibers, with a self-destruct system, formed by a body within which a tracer, an explosive in the central part and a lighter in the front part is worked out, characterized in that the self-destruct system is formed. two independent, physically different initiation systems (13, 20). The projectile charge missile of claim 1, wherein the first initiation system (13) is a mechanical inertia and the second initiation system (20) is thermal. 1 drawing