SE520700C2 - Fragmentation shell used as chaff against flying aircraft - Google Patents

Abstract

A low calibre projectile is used with the propellent charge centrally positioned. A shrapnel-generating projectile (1) comprises pieces of shrapnel (9), a case (11) surrounding the shrapnel pieces, and a detonator (6) for initiating the fragmentation charge (7). The projectile is shaped as a low calibre projectile with the propellent charge (8) located in a central axial position.

Description

20 25 30 35 szo 700 the projectile is at a suitable distance from the target, which is determined by means of a time tube or a zone tube with a small opening angle, throws splinters in the radial direction. If a splinter-generating projectile has a speed of 2000 m / s and the ejection of splinters takes place at a distance of 50 meters from the target, a radial launch velocity of approx. 100-200 m / s to obtain a diameter of the splinter notch of about 5-10 m at the target.

Due to the high projectile velocity, the splitter obtains a sufficiently high impact velocity in the target to give a good effect despite the fact that the radial launch velocity is kept relatively low. Compared to conventional explosive grenades, the explosive weight of the projectile, through the reduction of the radial launch velocity, can be reduced from 10-20 percent of the total weight to 1-2 percent. This means that the volume of the projectile can be radically reduced (by approx. 50 percent), which enables the projectile to be given an elongated design. This in turn leads to the air resistance of the projectile being low, which is a prerequisite for a projectile velocity of approx. 2000 m / s must be reachable. By accurately determining the burst point, the amount of splitter required for good effect decreases and thereby also reduces the projectile weight, which contributes to the projectile being able to be fired at a higher exit velocity.

The design of the new projectile leads to the majority of all splinters being concentrated on the target surface in question, while the splitter is given a sufficiently high speed to give a good effect in the target.

The invention will in the following be described in more detail by means of exemplary embodiments with reference to the accompanying drawing figures, in which: Figure 1 shows a side view of a splinter-generating projectile according to the invention and Figure 2 shows a section A-A according to Figure 1.

The splinter generating projectile according to the invention is designed to obtain low air resistance as a sub-caliber arrow projectile 1, see figure 1. The projectile 1 has a projectile housing 11 of solid material which can withstand the high acceleration in the cannon tube, for example steel, and is provided with stabilizing fins 2 to improve the ballistic trajectory of the projectile. Rotational stabilization is also possible. The fact that the projectile 1 is sub-caliber means that the inner diameter of the barrel is larger than the outer diameter of the projectile. When projecting from the barrel, there is a drive mirror when fired from the barrel, for example a so-called sabot, the outer diameter of which corresponds to the inner diameter of the barrel. The propulsion mirror provides a relatively high firing rate through the expansion of the propellants towards the large reaction surface. The speed increases along the entire length of the barrel. When the projectile 1 leaves the barrel, the propulsion mirror is released and disintegrates from the projectile 1, which continues towards the target at a speed that is significantly higher than that which could have been obtained with the corresponding firing with a full-caliber projectile.

The projectile 1 is equipped with a heat-resistant hood 3, figure 2, which has a heat-insulating effect on the projectile 1 and the parts behind the projectile. Behind the cap 3 is the projectile tip 4, inside which a cone-shaped front chamber 5 is arranged. Inside the front chamber 5 an ignition device with an ignition tube in the form of a time tube or a zone tube together with other parts of the ignition device and a battery is arranged. Furthermore, a lighter 6 is placed in the front part of the projectile 1 and in the center of an annular opening charge 7, see figure 2. A propellant charge 8 is centrally, axially placed in the projectile 1. The propellant charge 8 may for example consist of the heat-resistant explosive HNS.

The projectile 1 is designed to accommodate within the projectile housing 11 splinters 9 suitably in the form of spherical metal spheres, for example of steel or tungsten, embedded in a matrix of thermosetting plastic 10, such as an epoxy matrix. The metal balls 9 can be provided with release agents during the plastic casting in order to ensure that they remain smooth during the expulsion. The projectile casing 11 is suitably provided with longitudinal fracture instructions on the inside to facilitate the opening charge 7 to divide the projectile casing 11.

The function when the spark plug is activated is that the ignition device with the spark plug in the front chamber 5 initiates the igniter 6 which in turn ignites the annular opening charge 7 in the front part of the projectile 1 and then the centrally arranged propellant charge 8. When the opening charge 7 detonates the projectile shell 11 the longitudinal rupture instructions, after which the air resistance helps to remove the blown-out casing 11. The casing 11 is thereby cleared from the scale when the splitter 9 is pushed out by means of the propellant charge 8.

The centrally located drive charge 8 can be cylindrically designed, as shown in figure 2, but it can also be given a different shape depending on which splitter distribution is desired to be obtained in the impact surface. The propellant charge 8 can, for example, be designed as an elongate cone. Splitter 9 which lies at a narrower part of the propellant charge 8 will then be ejected at a less radial speed than splitter 9 which lies at a thicker part of the propellant charge 8. This means that a smoother spread of the splitter 9 in the impact surface is obtained. because splitter 9 which are located at different parts of the drive 10 ». , - .. 520 700 charge 8 due to varying radial launch velocity will hit the target at different distances from the longitudinal axis of the projectile. Since the housing 11 is removed earlier from the front parts of the projectile 1 than from the rear ones, it is suitable that in case the propellant charge 8 has varying thickness in longitudinal direction, for example if it is conformed, arrange the propellant charge 8 so that the thicker part thereof i.e. the part which gives the highest radial ejection speed of the splitter 9, is at the front.

To improve the splitter spread, you can also place a certain amount of splitter 9 in front of the opening charge 7. These splitters are not adjacent to any centrally arranged propellant charge that throws the splitter in the radial direction, but is only intended to continue straight ahead in the projectile. longitudinal direction.

If the spark plug consists of a time tube, this, unlike a zone tube, need not be located in the front part of the projectile 1, but can also be placed in the rear part of the projectile behind the propellant 8 and the splitter 9. The projectile 1 can in such case be provided with a compact carbide nose, giving the projectile 1 itself armor-penetrating capability.

Claims (8)

10 15 20 25 30. »- f. . Claims: Shatter-generating projectile comprising shrapnel (9), a shattered surrounding housing (11), an igniter and a propellant (8) arranged to project the shatter (9), characterized in that the projectile (1) is designed as a sub-caliber arrow projectile ( 1) with the propellant charge (8) centrally, axially located in the projectile (1). Projectile according to Claim 1, characterized in that the propellant charge (8) is cylindrically designed. Projectile according to Claim 1, characterized in that the propellant charge (8) is designed with varying thickness in the longitudinal direction. Projectile according to one of the preceding claims, characterized in that the projectile (1) comprises an opening charge (7) which is arranged to divide the projectile casing (11) during detonation so that the projectile casing (11) is cleared out of the way when the fragment (9 ) is pushed out by means of the propellant charge (8). Projectile according to Claim 4, characterized in that the projectile cover (11) on the inside is provided with longitudinal fracture instructions in order to facilitate the opening charge (7) for dividing the projectile cover (11). Projectile according to one of the preceding claims, characterized in that the projectile (1) is provided with a heat-resistant cap (3) arranged in front of the ignition device. Project according to one of the preceding claims, characterized in that the splitter (9) consists of spherical metal spheres embedded in a matrix of thermosetting plastic (10). Projectile according to Claim 7, characterized in that the metal balls (9) are provided with release agents during plastic molding in order to ensure that they remain smooth during expulsion.