NO130409B - - Google Patents

Description

Wing stabilized projectile.

The present invention relates to a wing-stabilized projectile, in particular a mortar shell for grenade launchers, where the projectile body in longitudinal section has an ellipse-like design, at the rear end has a steering device consisting of radial wings, and in the area of the largest diameter has circumferential grooves that lie on

oblique to the projectile's firing direction.

From the Norwegian patent document no. 120,173, it is known to arrange undercut circumferential grooves on the projectile body for wing-stabilized projectiles, where the grooves, seen in cross-section, are delimited by a front end surface which extends inwards at an acute angle in relation to the projectile surface and continues in a inner concave-curved part and then a concave-curved rear part with a greater degree of curvature. The purpose of deruic design is to avoid or at least significantly reduce projectile pendulum movements during the passage of the projectile, through the launch tube, by the fact that, as a result of the concave rear flank part of the groove, gas vortices occur between the projectile and the smooth surface in the launch tube, where the force effect of the gas vortices is directed largely radially towards the rudder wall. In this way, not only a vortex cushion is to be achieved, but also a living room effect for the propellant gases between the projectile and the rudder wall, whereby the impact movement of the projectile in the rudder is reduced.

The present invention aims to improve the design of the circular tracks on wing-stabilized projectiles that are fired through smooth rudders, thereby ensuring and increasing the favorable ballistic properties of the projectile body. For this purpose, the invention is based on a wing-stabilized projectile of the type mentioned at the outset, where the grooves are undercut towards the front of the projectile, and where the peculiarity consists in the fact that the side surfaces of the grooves, which are narrow, run parallel to each other and in a manner known per se in a straight line when seen on average.

With such an improved design of the circumferential tracks, it is achieved that the projectile, and especially a wing-stabilized projectile that is fired with a relatively high initial velocity, travels more slowly through the rudder, in relation to its axis, which leads to less dispersion and greater accuracy. Vortex formations are largely avoided by this design of the tracks. The back-up of the propellant gases improves. The parallel walls in

the narrow grooves cause a reaction force which is no longer radially directed but instead is directed obliquely backwards. Thereby, the propellant gases, which flow parallel to the tube wall, are effectively prevented from penetrating. The cancer game leads to a bending of the buoyancy effect around the tracks, in the projectile body. The living room zone makes it possible to capture the propellant gases in an optimal way

which tries to penetrate past the projectile, whereby the buoyancy pressure pad becomes more effective. The pro;'ectile body is thereby held so

that is to say, floating in relation to the walls of the launch rudder, whereby swinging impacts can be prevented more effectively than before.

The front edge of the ring groove is, when seen in section, advantageously sharp-edged and the rear edge can be chamfered or rounded.' In this way, the backward inclined position of the reaction forces can have a beneficial effect on the inflowing gases.

With respect to the depth, the circumferential grooves can be arranged in groups, the front group being suitably deeper than the rear group. There can be a greater distance between the track groups than between the individual tracks in the respective groups.

Furthermore, the tracks can run along a helical line around the projectile body in a manner known per se.

The front group of tracks is conveniently located immediately

at the largest diamter for the projectile. As a result of the greater depth of the circumferential grooves, the high static buoyancy gas pressure in the grooves is supported.

The invention will now be explained in more detail by means of exemplary embodiments with reference to the attached drawings. Fig. 1 shows a wing-stabilized projectile, seen from the side and partly in section, as they run around. tracks according to the invention are schematically indicated. Fig. 2 shows the design of the ring grooves according to the invention in section and on a larger scale. Fig. 3 shows in section and on an even larger scale two consecutive ring grooves according to the invention. Fig. h shows a. further embodiment according to the invention of the annular grooves on a wing-stabilized launch body.

The wing-stabilized projectile 1 comprises a projectile body 2, which, when actuated, is provided with a tail end, on which a steering device 1+ is arranged. The projectile body has, seen in longitudinal section, an ellipse-like design. In an area 5 at the largest cross-section of the projectile body, there is arranged a circumferential groove 6.

As will be seen from figures 2 and 3, the ring grooves have parallel running side surfaces 7a and 7b, while the bottom surface 8 of the grooves is slightly rounded. The inclined position of the tracks 6 in relation to the longitudinal axis of the projectile can lie in an angular range of around 50-30°. In the present embodiment, this angle is 9

on ^O<0>. The front edge 10 of the slanted grooves preferably forms a sharp edge, while the rear edge is designed with a chamfer 11 or a rounding.

It is sufficient to have only a few inclined grooves according to the invention at the largest cross-section of the launch body 2. In the present embodiment, eight such ring grooves are arranged. These are divided into two groups. The front group 6a, which comprises four ring grooves, has a greater depth than the grooves in the rear group 6b. Below this, the first group of ring grooves is located directly at the largest cross-section of the projectile body, while the rear group of grooves is located on the part of the projectile body that tapers towards the aft end. The reference number 1-2 denotes the wall of a smooth rudder, which forms the launching tube for the stabilized projectile. Between the rudder wall 12 and the projectile body 2, in the area of the largest projectile cross-section, there is only a small space 1'3, in which the damming of the launch gases must affect the projectile body to keep it in a position parallel to the launch rudder's longitudinal axis. The majority of this gas containment takes place in the inclined ring grooves in the front group 6a. The ring grooves themselves are relatively narrow. Their light opening can have a width of 2-3 mm, preferably 2.5 mm. The depth of the ring grooves in the front group is approximately 5 mm, measured along the center plane of the grooves. The grooves are somewhat wider than the space between successive grooves.

In the embodiment shown in fig. *+ there are also two groups of inclined ring grooves according to the invention and with mutually different groove depths. The distance 1^ between these two groups 6a and 6b is therefore greater than and preferably twice as large as the distance between the individual tracks within each track group. The gap shows the largest cross-section for the projectile body. Forward towards the tip of the projectile and backwards towards the aft end, the projectile body tapers, whereby the taper towards the aft end is stronger than towards the tip of the projectile body.

Claims (6)

1. Wing-stabilized projectile, special mortar shell for grenade launchers, where the projectile body in longitudinal section has an ellipse-like design, at the rear end has a steering device consisting of radial wings, and in the area of the largest diameter has circular grooves that lie at an angle to the direction of firing of the projectile as the grooves is undercut towards the front end of the projectile, characterized by the fact that the side surfaces (7a, 7b) in the grooves (6), which are narrow, run parallel to each other and which in and of themselves are rectilinear when seen in section. 2. Projectile as specified in claim 1, characterized in that the front edge (10) of the ring grooves (6) is sharp-edged and that the rear edge (11) is chamfered or rounded. 3. Projectile as specified in claim 1 or 2, characterized in that a front group (6a) of the ring grooves (6) is deeper than a rear groove group (6b). Projectile as stated in claim -1-3, characterized in that between the two track groups (6a, 6b) is a greater distance (1<*>+) than between the individual tracks (6) in each respective group. 5. Projectile as stated in claim 1-1!-, characterized in that the grooves (6) run in a known manner along a helical line around the projectile body. 6. Projectile as specified in claims 1-5, characterized in that the majority of the group (6a) which has the deepest groove is arranged in front of the largest diameter of the projectile.