NO138298B - DEVICE BY BOILER. - Google Patents

Description

Device for projectiles with stabilizing wings and high ballistic stability.

It is well known in firearms technology that the ballistic requirements are becoming stricter and

stricter due to the fact that the projectiles' output speed and range have been increased significantly. Consequently, projectile trajectories become longer and longer. The minor deviation during launch can therefore cause a very large deviation from the target.

Particularly sensitive in this regard are

projectiles with stabilizing wings, in which there is a significant pressure of combustion gases coming from nozzles that are parallel to the longitudinal axis of the projectile located between the wings.

It has been established that with such projectiles it is of the greatest importance to be able to ensure practically complete equality between the pressures that occur at the outlet of each nozzle, and complete parallelism between the longitudinal axes of the nozzles and the longitudinal axis of the projectile. These conditions must be met without the factory production of these projectiles being associated with large costs.

The present invention solves this task as a result of a large number of experiments and observations carried out during actual launches.

More specifically, the invention relates

a device for projectiles with stabilizing wings of high ballistic stability, where a one-piece head piece is attached to the rear end of the tubular motor and includes a tubular projection that serves as a guide for a thrust device

which brings the wings into the unfolded position

immediately after the projectile has been fired, and which headpiece also has openings at the bottom which are symmetrically arranged about the longitudinal axis of the projectile and are limited by two bores of different diameters, and where in each opening a nozzle is inserted which is formed by three parts, of which the first and the second have essentially the same length and diameter as the first and second bore respectively, and the third part constitutes the free length of the nozzle which is outside the rear bottom limiting surface of the headpiece. According to the invention, the first bore has a larger diameter than the second bore and lies within the rear bottom limiting surface of the head piece, while the second bore extends along almost the entire thickness of the head piece

bottom, and that the nozzles are externally limited by cylindrical surfaces with gradually decreasing diameters from the first to the second and from the ninth to the third section. Appropriately, the nozzles are fixedly connected to the head piece by means of fasteners which can be arranged in such a way that they simultaneously form a fixed connection between the two neighboring nozzles and the underlying part of the head piece, or they can be arranged individually for each nozzle in the form of two such diametrically opposite wedges for each.

The invention shall be explained with reference to the drawings where fig. 1 shows a diagram with a partial radial section of the main elements in a projectile with stabilizing wings, fig. 2 a view seen in the direction of the arrow F2 in fig. 1 with the cap removed, fig. 3 a section along the line III—III in fig. 2, fig. 4 a plan view of the one-part headpiece, and fig. 5 a section along the line V—V in fig. 4; fig. 6 shows in radial section the one-part headpiece according to fig. 5, combined with the nozzles, fig. 7 same view in the direction of the arrow F7, fig. 8 a modification of fig. 7, fig. 9 a section along the line IX—IX in fig. 7, fig. 10 a section along the line X—X in fig. 7 and 8 and fig. 11 a section along the line XI—XI in fig. 8.

The embodiment shown shows that on the rear end of a tubular motor 1 a head piece 2 consisting of a single part is attached, which at the same time constitutes an organ for the systematic channeling of combustion gases in the axis of the nozzles, a support for the joint connection of the different wings and a permanent control for the thruster of these wings. It must be considered a significant advance that such an element with different functions consists of a single piece.

As will be explained later, such a construction makes it possible to precisely assemble the elements which are to cooperate with a head piece consisting of a single part. This head piece is attached to the end of the motor 1 in such a way that the corresponding edge of the tube, as shown in fig. 1, rests against a parapet 3. The headpiece is provided on its rear surface with four pairs of ears 4, 5, and each of these pairs carries a pin 6. On each of these pins 6, the corresponding end of the stabilizing wing is pivotably attached . 7. These wings are made in such a way that, when they are closest to the longitudinal axis A—B of the projectile, their outer edge is located on a cylinder, the diameter of which is the same or approximately the same as the outer diameter of the tubular motor 1 . It also appears that the wings can be protected by a cap 8 which is placed on the protruding part of the head piece 2, as shown in fig. 1. The wings are firmly connected to each other by a thin connection plate 9 which simultaneously engages in a groove 10 with which each stabilization ring 7 is provided. This connection part 9, which is usually made of plastic material, is held in place by means of an elastic element 11 which is satnmen pressed between the connection plate 9 and the bottom 12 of the cap 8. As the cap 8 is supported on the protruding part of the head piece 2, the stabilizing wings 7 are completely protected. The head piece 2 is provided at the bottom with four holes 13; a nozzle 14 is placed in each of these.

According to the invention, the nozzles 14 are attached to the headpiece by being inserted into it and forcefully pressed into the openings 13 which are provided with a parapet 15. The nozzles themselves

is provided on the outside with a small shoulder 16 that fits the parapet. It has shown

It can be seen that with this device, without structural complications, the nozzles can be given a very large support surface against the head piece 2. By increasing this support surface to a considerable extent, the nozzles can also be kept immobile and firmly connected to the head piece in an approximately mathematically correct position with the longitudinal axis completely parallel to the projectile's longitudinal axis A—B.

As the nozzles 14 are firmly connected to the head piece in the manner described, it is possible to connect the nozzles even more firmly to each other by arranging fastening wedges 17 which are precisely inserted between two nozzles and in the head piece 2, if shown in fig. 7, or which is individually inserted between each nozzle and the head piece 2, as shown in fig. 8.

Finally, one of the most important advantages of this special arrangement of the nozzles, which are pressed into the openings in the head piece from the inside, is that the greater the pressure of the flowing gases, the better the nozzles are held in the head piece, which also means an advantage in considering that the ballistic stability of the projectile is dependent on the correct position and stability of the nozzles.

The one-part head piece 2 is also provided with a tubular internal axial projection 18 which over almost its entire length has a bore with a slightly larger diameter than the diameter of the opening that opens into the front surface of the head piece 2. In this tube-shaped element 18, a bolt 19 is introduced which belongs to a sliding device for the wings and serves to bring them into the extended position. This bolt consists of a cylindrical part which is extended at one end with a cylindrical part 20 and a threaded end part. The other end is extended with a head and has a neck. The cylindrical part of the bolt is provided with a knurled part at the head 22 over a certain length. The cylindrical part has such a diameter that it can be introduced with light friction into the opening in the projection 18 with the smaller diameter; the diameter of the head is chosen so that it can be introduced with light friction into the bore in the projection 18 with the larger diameter. A sealing ring 27 is placed under the head 23.

A cross-shaped pusher 28 is pushed into the part 20, whose arms each touch a ledge 29 on the wings 7. This cross-shaped pusher 28 is firmly connected to the bolt by means of a nut 30. A sealing ring 31 is inserted between the head piece 2 and the slider 28.

This pusher device cooperates with the wings 7 ledges 29 in that the cross-shaped pusher 28 in the extended position of the wings forms a locking stop, as shown by dash-dotted lines in fig. 3. In this position, the push device is to a certain extent wedged in the head piece 2 by the fact that the grooved part of the bolt is forced into the narrow part of the opening in the head piece projection 18. The outlet opening of each nozzle 14 is provisionally closed with a plug-shaped capsule 32 of light -■metal. One of these capsules 32 is shown in fig. 6.

These various improvements are all related to the construction of the one-piece head piece, in which the nozzles are inserted from the inside and wedged, and the special arrangement of the thrust device for the wings. With the help of this combination, it is achieved that the nozzles can be easily and quickly pressed into the openings in the head piece, and it is ensured that their central axes are oriented parallel to the projectile's central axis A—B. In this way it is also ensured that when the pressure in front of each nozzle is the same, not only is the pressure behind it also the same for each nozzle, but the gas flows are directed exactly correctly out of each nozzle; as the nozzles are arranged symmetrically around the longitudinal axis of the projectile, the greatest possible ballistic stability is achieved. A rather small convergence or divergence of a gas stream flowing out of the nozzles in relation to other gas streams can cause a large change in the trajectory of the projectile and bring it out of this.

The thruster's control and tight fit ensure an equal mechanical load on the wings and a completely symmetrical spread of the four wings in relation to the longitudinal axis of the projectile, i.e. also in relation to the trajectory of the projectile. However, it is also known that the slightest change in the angular distance between one wing and another wing can cause an incorrect trajectory. Therefore, the cross-shaped part of the thrust device only acts as a stop without exerting any blocking effect. In the latter case, it is difficult at the same time to effect the same fit between the free ends of the branches of the cross-shaped pusher and the groove arranged in the adjacent part of the corresponding wing. At the moment of fitting in, a movement of the wings occurs which must be prevented.

The almost mathematically exact arrangement of the position of the nozzles is also ensured

by the arrangement of the fastening wedges 17 which can be arranged because the nozzles engage in the interior of the head piece.

Claims (4)

1. Device for projectiles with stabilizing wings with high ballistic stability, where on the rear end of the tubular motor is fixed a head piece which is in one piece and comprises a tubular projection which serves as a guide for a thrust device which brings the wings into the unfolded position immediately after the projectile has been fired, and which headpiece also has openings at the bottom which are symmetrically arranged about the longitudinal axis of the projectile and are limited by two bores of different diameters, and where in each opening a nozzle is inserted which is formed by three parts, of which the first and the second have essentially the same length and diameter as the first and second bore respectively, and the third part constitutes the free length of the nozzle which is outside the rear bottom limiting surface of the headpiece, characterized in that the first bore has a larger diameter than the second bore and lies within the rear bottom limiting surface of the headpiece, while the second bore extends along almost the entire thickness of the bottom of the headpiece, and that the nozzles are externally limited by cylindrical surfaces with gradually decreasing diameter from the first to the second and from the second to the third part. 2. Device according to claim 1, characterized in that the nozzles are firmly connected to the head piece by fastening wedges. 3. Device according to claim 2, characterized in that the fastening wedges are arranged in such a way that they simultaneously form a fixed connection between the two neighboring nozzles and the underlying part of the head piece. 4. Device according to claim 2, characterized in that the fastening wedges are arranged individually for each nozzle and that two such diametrically opposed fastening wedges are arranged for each nozzle.