CS200077B1 - High explosive shell wits splinters formed by explosive cherge - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bursting projectile with shatter-shaped fragments, in which it is desired to achieve the maximum fragmenting effect for a given target while maintaining its other properties.

Enhancement of the shattering effect of missiles is solved by a number of design modifications. Their task is to achieve an advantageous splinter field resulting from the disintegration of the shell of the projectile into splinters of desired properties and their uniform distribution in the space of the splinter field. This achieves the maximum effect of the missile missile in the target. A serious task is to create a suitable shard. The properties of the fragments can be defined by their size, shape, specific gravity, take-off or impact velocity, the angle of impact on the target and other additional characteristics determining their ability to destroy the target. For the bullet body is used almost exclusively steel. In this way, it is possible to limit the main characteristics of the fragments to their size, shape, impact velocity and angle of incidence. A small number of shards is required to eliminate the target. One, at most a few fragments, is enough to eliminate a living force or damage an important mechanism of the technique if the intervention is effected by an effective splinter. An effective shard is one that is commensurate with its properties to the target. Increasingly, the shattering effect of missiles against light armored technology is required. Only shards with sufficient kinetic energy, of a suitable shape, piercing the armor with an impact angle close to the perpendicular impact, can break through the armor and destroy important mechanisms or eliminate the live force hidden behind the armor. Such a shard is hardly up to 200 077

200 077 and applicable to the current construction wiped. For missiles without pre-shaped fragments, the projectile explosion creates a large number of too small fragments lacking enough energy to break through the armor. Furthermore, a smaller number of medium and large fragments will be produced with different impact velocities and in most cases with an inappropriate impact angle. The effect of the missile against the armored targets ea will only manifest itself in the immediate distance from the impact site of the missile. In most cases, fragments of varying effect are produced, depending on the design parameters of the missiles, which are not pre-selected according to the characteristics of the targets, but are indispensable to the established practices used in the design of ammunition.

Recently, much attention has been paid to this problem. Special designs of 8 shell shells were designed, between which preformed shells of different types, made of various materials, are inserted. Another way of modifying bullets leading to its distribution into suitable fragments is to modify the shell of the bullet. It consists in that the shell of the projectile is divided by notches, bosses or otherwise, so that after the explosion of the tear charge the shapes of fragments predetermined by this damage to the shell of the projectile body are achieved. Both the first and second methods of modifying the bullet casings complicate their overall arrangement and reduce their strength. Technology of production of such missiles complicates, the price increases and only the number of shell shells can be used in this way.

The above-mentioned drawbacks are eliminated according to the invention in that the essence of a shatter-burst projectile with shrapnel-shaped shells consisting of a bullet body, lighter, basic tear charge and a peripheral firing element is that the shredder consists of shaped blasting bodies adapted to elongated charges. assembled on the inner surface of the bullet body in columns and rows and surrounding an internal tear charge composed of an upper tear charge and a lower tear charge. The peripheral tear charge is initiated first. Its action shatters the shell of the projectile and initiates an internal tear charge. This achieves the distribution of the shell of the projectile into suitable fragments and their flight into the desired direction.

In this way it is possible to obtain preformed shells even in highly stressed ammunition, which has not been possible so far, but also in less stressed shells, in which various modifications of the shell of the shells have been applied, these jerky charges can be used to obtain suitable shells.

An exemplary embodiment of a missile according to the invention is shown in the drawings, wherein Fig. 1 shows the principle of uncoupling the steel plate, Fig. 2 shows the principle of uncoupling the steel plate and preformed fragments therein;

Thus, the explosive bodies 4 threaded onto the protruding charges 4 are placed in several columns and rows side by side. The charges 2 are adapted to be initiated simultaneously when ignited. The detonation wave passing through the longitudinal charge 2 in the longitudinal direction is relatively faster than the radial wave initiating explosive bodies. The damping may result in geometric accumulation of detonation waves of adjacent explosive bodies 6 in both rows and columns. The explosive bodies 6 are cylindrical in shape with bevelled edges. The steel plate 6 is of the same thickness compared to the diameter of the bodies.

Initiation is initiated by an impulse delivered by an electric igniter by means of a firing guide 6 on a firing pin mounted in the detonator 6 provided in the sleeve 6. As shown in FIG. 1, detonation detonators 6 are simultaneously initiated by explosive charges. The detonation waves in these draw3s

The 200 077 charges 2 extend in the longitudinal direction relatively faster than in the radial direction. This is due to the small delay caused by the necessary transition of the detonation energy by braiding, insulation and the air layer between the explosive bodies χ and the protruding charge of the explosive 2. At the interfaces of the explosive bodies 6 a geometric accumulation of the detonation wave occurs by cutting the steel plate 6 into regular quadrangles, geometrically identical with the dimensions of the explosive bodies χ as shown in FIG. 2. FIG. 3 illustrates the practical application of the invention to a relatively complex projectile so as to demonstrate the technical applicability of the principle of the invention. It can be assumed that the application of the principle will be on less complex objects.

The missile was mainly simplified its outer shapes and components. The bullet body 8 is provided with a bottom 2 bullets. A contactless lighter X with an initiated initiation cap 12 in the lower part of the projectile is contemplated. Explosive bodies χ are of two types - conical in the ogival part of the projectile, cylindrical bullet in the cylindrical part. The explosive bodies χ are rigidly threaded onto the protruding charges 2 in several rows, thus filling the perimeter of the inside of the projectile body 8. At the upper portion of the bullet, the ends of the protruding charge 2 are fixed in a split upper sleeve 10. the cartridge 14 so that it cannot be initiated directly from the priming housing 12 or the protruding charge

2. The upper tear charge 13 and the lower tear charge 14 expand the peripheral bodies 6. The plastic ring 15 and the plastic split washer 16 secure the entire assembly in the projectile body 8 and are closed by the bottom 2 of the projectile. The connection of the contactless lighter X with the priming cartridge 12 of the priming case 12 is made by the ignition conductor 6. Technological adjustments necessary for firm connection of individual parts of the assembly etc. are omitted.

The missile function begins as soon as it approaches the desired distance to the target. The non-contact lighter χ connects the circuit of the lighter X to the starting case 12 via conductors 4. At the next moment, the detonating cord 2 is simultaneously initiated, through which the detonation wave passes towards the projectile tip. The initiation of explosive bodies χ will be delayed because the longitudinal detonation wave in the direction of the protruding explosive charge 2. - detonating cord - proceeds relatively faster than the transverse - radial detonation wave, which spreads by braiding, insulation and air layer into the explosive body χ. The detonation wave caused by the initiation of explosive bodies χ manifests itself as a normal detonation and as a cumulative detonation at the interface of shaped charges. This rectified detonation wave causes the formation of geometrically uniform fragments of the projectile body 8. Both tear cartridges 14 and 13 are also initiated by detonation propagating from the explosive bodies χ. By the combined action of the detonation waves, the fragments are directed in the direction of gradual initiation perpendicularly and obliquely to the missile axis. Under the action of the other forces acting on the projectile, the fragments velocity vectors receive a spatial distribution in the cone whose apex is determined by the point of initiation of the projectile. By selecting the weight and shape of the explosive bodies χ, it is possible to influence the size and shape of the fragments formed after the initiation of the projectile. This allows the choice of effective shards based on the occurrence of probable targets, even those requiring high energy to be discarded. The uniform distribution of high-efficiency fragments in the space of the splinter field gives a high chance of silencing targets with weak armor that protects the upper parts of modern combat technology.

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It is not. precluded the application of this principle to unarmed ammunition. Wherever it is necessary to produce highly efficient shards formed only by a bursting charge, this application may be advantageous.

Claims (1)

A three-breakable bullet with fragments, shaped by a detonating charge, consisting of a bullet body, a lighter, a basic burst charge, and a peripheral priming component, characterized in that the detonating charge is formed by shaped detonators (1) modified to draw charges (2) and an inner surface of the bullet body (8) in columns and rows and surrounding the upper tear charge (13) and the lower tear charge (14).