SE529751C2 - Belted projectiles, their use and manufacture - Google Patents

Abstract

In its simplest form the present invention comprises a new method for manufacturing projectiles (1, 11-12 and 19) provided with bands (4, 9, 16), whilst according to a further development of the invention, the facility is afforded for manufacturing artillery projectiles (1, 11-12) according to the same basic principle, which can alternatively be launched from a rifled barrel with or without any spin, along with the facility, according to a new method, for launching spin-free projectiles (6) from rifled barrels without the use of so-called slipping plastic bands.

Description

20 25 30 35 529 751 1065 sE 2 fenstabilized full-caliber projectiles with long firing range and undercalibrated armor-piercing, likewise fenstabilized arrow projectiles. Since such projectiles, which must be fired without rotation, can often occur inside an ointment with other projectiles that require rotational stabilization, it is not a practical solution to the problem to change barrels between the projectile types.

Conventional rotation-stabilized projectiles fired from shelled barrels are rotated by a co-operation between a soft metal, usually copper, a belt and the barrel shafts' barriers. In order for the belt, which has not been initiated by the barrel fox fl to be initiated, to be able to be completely and completely transferred to the projectile in question, it is required that the belt is both non-rotatable and inextricably connected to the projectile. The conventional method for producing artillery projectiles equipped with metal belts has therefore hitherto involved pre-manufacturing the annular belt with an inner opening diameter which made it possible to thread it over the projectile in question and then under high pressure while reducing the outer and inner diameter of the belt. it in a similarly prefabricated groove in the projectile in question. For the production of heavy-caliber artillery garrisons, large presses have therefore been required, which of course has made the production more expensive.

OBJECT OF THE INVENTION AND ITS FEATURES An important object of the present invention is to provide an improved method of producing projectiles provided with belts, which projectiles are intended to be fired from fired fire tubes, which method at least substantially reduces, preferably eliminates, in said description said problems. The beneficial effects of belted projectiles can be utilized in a better way than before.

The said objects, as well as other objects not listed here, are satisfactorily fulfilled within the scope of what is stated in the present independent patent claims. Embodiments of the invention are set out in the dependent claims.

Thus, according to the present invention, there has been provided an improved method of manufacturing belted projectiles for firing from coiled fire tubes which is characterized in that the belt of the projectiles annealed to its basic shape via an internal thread joins the projectile body via a longitudinal outer surface thereof. , corresponding thread. 10 15 20 25 30 35 529 751 1065 sE 3 According to further aspects of the methods according to the invention: that the belt, when the projectile is intended to be fired is rotationally stabilized, after the belt has been threaded on the projectile body, but before the firing, ejection direction rear stop position. when firing one and the same belt-equipped projectile type from fired fire tubes, enable a choice between a completely rotation-free firing of the projectile in question and a corresponding rotating firing of it against fire tube foxes, the projectiles' belts being provided with an internal thread threaded on an opposite thread on the projectile body and whereby the belt, if the launch is to take place without rotation, is applied in the projectile direction of the projectile at the front of the projectile body's external thread and this external thread, which is designed with the same thread direction as the barrel and with at least the number of turns the belt to rotate during firing through the barrel and whereby the belt's rotation possibilities, when full rotation is desired on the fired projectile, are blocked before firing. that the possibility of rotation of the belt, when full rotation of the fired projectile is desired, is blocked by threading the belt backwards in the intended projectile direction of the projectile along the projectile body's projectile towards a stop position which ensures when firing without rotation of projectiles that are fired with the aid of belted drive mirrors, ensure that resp. drive mirror is completely freed from its resp. belt when the drive mirrors leave the barrel, the drive mirrors being provided with external threads on which resp. belts fitted with internal threads are threaded to resp. the main position of external threads in the intended firing direction of the projectile and whereby these threads are formed with a number of thread turns which is slightly less than the number of turns included in the barrel shaft. to produce belt-equipped full-caliber projectiles intended to be fired from knurled barrels either completely rotationally free or with the rotation generated by the barrel of the barrel used in the launch, the projectile being produced in the form of two screwed projectile parts of which one projectile part has a which is designed so that it can be inserted into a recess provided with a corresponding internal thread in the second projectile part and a one of the projectile parts in connection with the joining between them has a turned-down and for threading the internally threaded belt threaded portion on which the belt is threaded before the projectile parts are screwed together.

Furthermore, according to the invention, the belted projectile intended for the practice of the methods according to the invention is characterized in that the belt is connected to the projectile by means of its own internal thread and a corresponding external thread arranged along the outside of the projectile, which threads cooperate with each other.

According to further aspects of the belted projectile intended for the practice of the methods according to the invention: that the projectiles can be fired completely without rotation, alternatively during the rotation initiated by the barrel spindle, each projectile comprising an external thread on which, in itself an annular belt, which in itself comprises a corresponding internal thread, is threaded, and wherein these two threads have the same thread direction as the barrel fox fl none and wherein the projectile's external thread has such a selected thread pitch and thread length that it allows the adapted, internally threaded belt to be slid into in the projectile firing direction front position to a rear position in the projectile firing direction and that this movement includes at least the number of thread turns corresponding to the number of revolutions that the barrel rä no one has along the entire barrel. that when the belted projectile is intended to be fired from a barrel of barrel, which it is to leave completely without rotation and wherein the projectile is comprised of an undercalibrated in its path towards the target fenstabilized armor-piercing arrow projectile, which is fired from the barrel in question by means of a drive mirror, which in turn has an external thread on which the belt with an internal thread included therein is threaded and wherein the thread of the drive mirror is adapted to its length so that the belt leans the drive mirror in connection with the projectile learning the barrel. 10 15 20 25 30 35 529 751 1065 si: 5 that its belt is provided with breaking instructions which ensure that the belt is broken into several parts in connection with it being threaded by the drive mirror and thus leaving it.

ADVANTAGES AND EFFECTS OF THE INVENTION: In its basic embodiment, it is now proposed in accordance with the present invention that the belt, instead of being pressed into a groove in the artillery projectile, be joined to the projectile in question by being threaded onto the projectile body. Since each belted artillery projectile must normally have the same diameter in front as behind the belt and since the method according to the invention to thread the belt on the projectile body does not simultaneously include a diameter reduction on the belt, the method according to the invention normally means that artillery projectiles joined parts together. Of these two parts, according to this variant of the invention, one is formed with a turned-down and threaded end portion against whose inner part the belt is threaded on and whose outer part is screwed into a similarly threaded recess in the other projectile part. Thus, in the case of projectiles provided in the manner indicated above, the threaded belt will be a submerged groove, which in the direction of one end of the projectile is delimited by the end edge of the turning and in the direction of the other end of the projectile is delimited by the other edge of the projectile part.

A special case that will be discussed in more detail later are belted so-called driving mirrors for undercalibrated arrow projectiles.

Thus, in its simplest form, the present invention provides a method of attaching the internally threaded girdle to artillery projectiles by means of an external screw thread arranged on the latter instead of forcing the girdle into a groove in the projectile.

This new method has several advantages.

In its basic design, the invention thus means, in that the high-pressure pressing of the belt is no longer necessary, that the production becomes cheaper. This is despite the fact that the method according to the invention means that the artillery grenades must be produced in two interconnected parts. The production of these two grenade parts can in fact be done without problems in the same vending machines that have previously been used for the production of grenades in one piece. In addition, according to further developments of the invention, there are the possibilities of producing artillery projectiles according to the same basic principle, which alternatively according to one's own choice, can be fired with or without rotation from fired barrels and the possibility of firing non-rotating according to a new method. projectiles from refractory barrels without the use of so-called slippery plastic belts, which as will be seen below have fl your disadvantages.

If you want to shoot a fenstabilized projectile out of a barrel of barrels without the projectile being caused to rotate by barrel barrels, then with today's technology you must use a projectile equipped with a so-called slippery girdle. The sliding belt, which replaces the copper belt of the conventional rotationally stabilized projectile for non-rotating firing, has in principle approximately the same shape as the copper belt, but the sliding belt is made of polyacetal or other plastic material. However, the slippery belt is not an ideal solution to the problem, even if it has a very large spread. The slippery plastic belt seals e.g. not as good against the shredded inside of the barrel as a non-slippery copper belt and it thus contributes to lowering the projectile's initial velocity V0 and it is also not uncommon for slippery plastic belts to have so-called "Blow by", which means that sufficient amounts of gunpowder gases leak past the belt to damage the front part of the projectile, which can cause serious problems in e.g. "Intelligently controllable ammunition". Additional disadvantages of the so-called the slippery belt is that, because it must be made of a relatively soft material until firing, it is always very sensitive to external damage. In addition, it is very tricky to design slippery plastic belts with the right slippery properties. The testing of new types of projectiles with sliding belts will therefore always be very costly. Finally, the sliding belts are difficult to mount because they easily get residual deformations during mounting as the mounting normally means that the closed belt ring is pressed over a guide roller on the full caliber grenade or on the drive mirror at the undercalibrated arrow projectile.

The present invention now entails a solution to the above-mentioned problems which means that in the future it will also be possible to use metal belts, e.g. copper belts when firing non-rotating projectiles from shelled barrels.

In addition, the invention means that one and the same projectile at a late time right up to just before the launch and without actual rebuilding will be able to be switched from, according to a first variant or mode, leaving a trace of barrel as a non-rotating projectile, which is a precipitation of stabilization fins, if it initially contains the necessary control functions, could also be steered towards the intended target, in order to function in its second variant when fired from the same barrel as a completely conventional rotating projectile without that fins included in the projectile are allowed to fold out. The latter variant is thus suitable for e.g. short firing ranges that do not allow precipitation of fins and where control functions cannot be used. The present invention thus makes it possible to use one and the same type of grenade for two different target types, each of which previously required a different type of grenade.

Non-rotating, fin-stabilized artillery projectiles belong to the state of the art and it is thus known fl your various ways of designing fins and fin precipitation mechanisms utilized in such projectiles and devices for determining / when and whether the fins are to be precipitated. Since these details do not form part of the actual invention, they will not be discussed further here either.

According to the present invention, the problem of producing a metal belt equipped artillery projectile is now solved, which can be fired from a barrel of fire tubes either completely without rotation or at full rotation by rotating the projectile's annular copper belts via an internal thread rotatably on an external thread on the projectile body. The basic idea behind the invention is thus that if a projectile of the type characteristic of the invention is fired from a rifle barrel and if it is desired that the projectile should leave the barrel without rotation, then the belt, then the rafter no one forces it to rotate, should not transmit its own rotation to the projectile but instead use it to move in the projectile's firing direction backwards along the projectile thread. In order for this to work, it is therefore required that a sufficient number of thread turns is available in the projectile's firing direction behind the belt on the projectile and that the thread direction of the projectile's and belt's threads coincides with the barrel direction of the barrel. During firing, the sliding rotation of the sliding belt relative to the projectile body is thus replaced by the rotation of the threaded copper belt and for moving backwards along the thread on the projectile body. If the belt's ability to move along the projectile thread is instead blocked before firing, the belt's rotation will be transferred unchanged to the projectile, which will then leave the barrel from which it is fired as a completely conventional rotation-stabilized projectile. The simplest way to achieve such a blockage of the ongoing belt is, of course, to thread it down towards a stop which limits the projectile access backwards in the projectile direction of firing.

A projectile or grenade of the type characteristic of the invention is thus characterized in that it is provided along its mantle surface with an external thread on which an internally threaded copper belt is threaded. In order to make the projectile adjustable between a non-rotating and a rotating firing, the length of the projectile thread with the belt threaded in a forward position behind the belt must contain at least the number of turns of the barrel intended for firing the projectile in question. exhibits groove turns.

With the belt in this forward position in the firing direction, the projectile in question will leave the barrel without rotation. If the belt is instead screwed backwards in the firing direction towards a fixed rear stop position, the projectile will leave the barrel as a rotation-stabilized projectile with a full rotation for the barrel used.

The barrel of the Bofors 57 mm automatic cannon, which needs to be able to fire both rotation-stabilized explosive grenades and fin-stabilized non-rotating armor-piercing arrow projectiles, has a groove pitch that gives a rotation of 24x57mm. In everyday speech, it is said that the barrel has a 24 caliber rifle pitch. This means that a rotation-stabilized grenade makes a turn of 1368mm barrel length. Since the barrel length is 57x70 ie. 3990mm, the grenade rotates 3990/1368 = 2.9 turns during its journey through the barrel. When a rotation-stabilized projectile is fired from such a barrel, it has a rotation that is about 45000 rpm if the initial velocity is 1025 m / s.

Since the barrel torque never corresponds to more than a few revolutions, the play that may occur in front of or behind a belt mounted according to the invention, depending on whether rotating or non-rotating firing is desired, will never interfere with the ballistics of the projectiles to any great extent.

While the full projectile according to the invention, regardless of whether it is fired rotating or non-rotating and thus also regardless of whether the belt when the projectile leaves the barrel is in its front or rear position, can just as easily keep the belt after leaving the barrel, the position is the opposite when applies to undercalibrated armor-piercing arrow projectiles, which are fired with the help of so-called propulsion mirrors which are to leave the actual projectile as soon as it has left the barrel muzzle. There it is thus an advantage if the drive mirror thread is so adapted that the belt is threaded from the drive mirror at the right time and to avoid the detached belt damaging the arrows of the arrow projectile, the belt can in this variant be supplemented with breaking instructions that ensure it is divided into smaller parts. as soon as it left the drive mirror. By replacing the previously used slippery belts on the drive mirrors of the undercalibrated anti-tank arrows with in-line designed copper belts, which are threaded off during the projectile's travel through the barrel, it is also advantageous to replace the fractures or similar structures previously used to hold together the drive mirrors consisting of olika your various parts. As long as the belts are along the thread of the drive mirror, they will of course effectively hold the parts of the drive mirrors together and then release them as soon as they have left the thread.

LIST OF FIGURES The invention has been defined in the following claims and it will now be described somewhat further in connection with the accompanying figures.

Of the figures, Fig. 1 shows a side view of a first embodiment of a projectile according to the invention in the form of an artillery grenade adapted for firing without transferring rotation to the grenade, Fig. 2 a side view of the artillery grenade according to Fig. 1 adapted for firing with full rotation of the grenade after the grenade has left the barrel, Fig. 3 is a partially sectioned side view of a second embodiment of a projectile according to the invention in the form of an undercalibrated arrow projectile, here of the anti-tank arrow type, which is fired without transmitting rotation to the anti-tank arrow itself.

Fig. 4 is a front view of the metal belt for the anti-tank arrow in Fig. 3, and Fig. 5 is a partially sectioned side view of a grenade produced in accordance with the invention, adapted for firing without rotation being transferred to the grenade.

Fig. 6 is a partially sectioned side view of a grenade produced in accordance with the invention in its simplest, non-adjustable design with rotating height of the grenade.

DETAILED DESCRIPTION OF THE EMBODIMENT The projectile 1 shown in Figs. 1 and 2, here especially in the form of an artillery grenade 1, is designed in accordance with the basic principles of the invention and thus provided with a portion 2 slightly turned away from its own shell surface, which is provided with an external thread 3. A metal belt 4 internally threaded with the same thread, preferably of 10 copper, is in turn threaded on the thread 3. For the thread 3 its thread direction corresponds to the groove direction at the barrel through which the grenade 1 is intended to be fired, and that its thread pitch is so selected that the thread 3 within the accessible turned-down portion 2 allows a rotation of the in-place mounted with the same thread internally threaded copper belt 4 by at least the number of turns generated by the current barrel.

Fig. 1 shows the variant of the invention where the copper belt 4 is in its forward position in the projecting direction of the grenade 1, whereby the belt 4, when it is forced to rotate by a barrel of barrel of barrel nobody, will move along the thread 3 backwards. in the firing direction a of the grenade 1 without thereby transmitting any rotation to the grenade 1. The grenade 1 will thus leave the barrel completely without rotation.

Fig. 2 shows the same grenade 1 as in Fig. 1, but here the copper belt 4 has already before the firing been screwed back to a certain stopping position, for example comprising a stopping edge 5 which at the rear in the intended firing direction a of the grenade 1 defines the turned-down portion 2. In this variant thus the backward movement of the belt 4, seen in the firing direction a of the grenade 1, is effectively blocked, so that the rotation of the belt 4 which the barrel fox fl no one generates will be transmitted without limitation to the grenade 1 which will thus leave the barrel during full rotation.

Fig. 3 shows a barrel projectile in the form of an undercalibrated arrow projectile 6, for example an armor-piercing anti-tank arrow stabilized on its flight towards the target, provided with a divided drive mirror 7, which drive mirror 7 has a rear threaded portion 8 on which portion 8 has a corresponding threading Sa internally threaded metal belt 9, for example of copper, is threaded. Thread 8-88 is designed so that the rotation of the belt 9 which the barrel shell generates during firing has time to thread the belt 9 in connection with the projectile 6 in question leaving the barrel from which the projectile 6 is fired. At the same time as the belt 9 leaves the drive mirror 7, its cohesive function on the different parts of the drive mirror 7 also ceases. In order that the belt 9, when detached from the driving mirror 7, should not damage the fins 6 ”of the arrow projectile 6, the belt 9 has been provided with the breaking instructions 10 illustrated in Fig. 4 which ensure a division of the belt 9 into several smaller parts. Fig. 5 has in particular been included to illustrate a suitable way of producing grenades 1 of the core artillery projectile type for the invention. Accordingly, the grenades 1 are produced in two parts, ll resp. 12, which are screwed together by means of an internal and an external thread 13 resp. 14. This makes it easy to produce the external thread 15 characteristic of the invention and to thread it on the belt 16 threaded with the internal thread 15a before the grenade parts 11 resp. 12 are screwed together. In Fig. 5 there is also a common internal space 17 filled for the grenade parts 11 and 12, respectively, and a gasket 18 is drawn. Fig. 5 also shows the same stop edge 5 for the rearward displacement of the belt 16 in the direction of ejection a of the grenade 1 as in Fig. 2 and since the stop edge 5 has the same function here too, i.e. that the belt (16) is threaded down to abut against a rear stop position (5), here in the form of said stop edge 5, it has been allowed to retain the designation 5.

Fig. 6 shows a further embodiment of an artillery projectile of the grenade type produced according to the invention. This grenade 19 is also made of two interconnected grenade parts 21 and 22, but the grenade 19 is here of a simpler non-adjustable type. The grenade 19 is also provided with a metal belt 20 fixed by thread, preferably of copper. Since the grenade 19 is only intended for rotary firing, its copper belt 20, in addition to being threaded on the rear grenade part 22, is also fixedly fixed between the grenade parts 21 and 22.

As further shown in Figure 6, the grenade part 21 is formed with an internally threaded bore 24 whose thread has the designation 24a, while the grenade part 22 has a joint part 25 adapted to the bore 24 and externally threaded with the thread 25a. The belt 20 is in turn formed with an internal thread 20a. All these threads are adapted to each other and the belt 20 has first been screwed onto the joint part 25 and then the grenade parts 21 and 22 have been screwed together.

Joined, the grenade parts 21 and 22 have a common explosive-filled space 23. The designation 26 indicates a gasket or sealing compound.

ALTERNATIVE EMBODIMENTS The invention is not limited to the embodiments shown, but can be varied in various ways within the scope of the claims.

It will be appreciated, for example, that the terms artillery, artillery piece, cannon, artillery projectile, artillery grenade, projectile, arrow projectile, etc. above refer to all types of barrel weapons with associated projectiles which include some form of shelling, , conventional artillery, troop support weapons, etc.

Claims (10)

10 15 20 25 30 35 529 751 1065 sE 13 PATENT CLAIMS Methods of producing projectiles (1, 6, 11 + 12, 19) equipped with belts (4, 9, 16, 20) intended to be fired from fired fire tubes, characterized by the projectiles' (1, 6, 11+ 12, 19) in its basic form annular belts (4, 9, 16, 20) are connected to the projectile body via an internal thread (Sa, 15a, 20a) via an external, corresponding thread (3, 8, 15, 25a) applied along its outside ). 2. A method requirement, characterized in that the belt (4, 16, 20), when the projectile (1, 11 + 12, 19) is intended to be fired rotationally stabilized, after the belt (4, 16, 20) has been threaded on the projectile body, but before firing, the projectile body is relativtxerted at a rear stop position (5) in the projectile firing direction (a). 3. In any case, claim 1 or 2, it is known that when firing one and the same belted (4, 16) projectile type (1, 11 + 12) from fired fire tubes, enable a choice between a completely rotationally free firing of the projectile (1, 11 + 12) in question and a corresponding non-rotating projectile against the barrel fox fl, whereby the projectiles (1, 11 + 12) belts (4, 16) are provided with an internal thread (l5a) which is threaded on a corresponding external thread (3 , 15) on the projectile body (1, 11 + 12) and whereby the belt (4, 16), if the launch is to take place without rotation, is applied in the projectile launch direction (a) at the front of the projectile body's (1, 11 + 12) external thread ( 3, 15) and wherein this external thread (3, 15), which is designed with the same thread direction as the barrel of the barrel and with at least the number of thread turns as the barrel of the barrel, forces the belt (4, 16) to rotate during the firing through the barrel and the belt ( 4, l6) rotation possibilities, when fun rotation is desired on the foam projects (1, 11 + 12), biocage phase (5) before launch. 4. If any of the requirements, 2 or 3, it is felt that the possibility of rotation of the belt (4, 16), when full rotation of the fired projectile (1, 11 + 12, 19) is desired, is blocked by the belt (4, 16) before the projectile's (1, 11 + 12) projectile was fired backwards in the projectile's (1, 11 + 12) intended firing direction (a) along the projectile body (1, 11 + 12)'s external thread (3, 15) towards a stop position (5) which ensures that the rotation which the barrel fox fl no one forces on the girder1n (4, 16) is completely transferred to the projectile body (1, 11 + 12). 10 15 20 25 30 35 4529 751 1065 sE 14 Method according to claim 1 for firing without rotation of projectiles (6) which are fired by means of belted (9) drive mirrors (7) ensure that resp. drive mirror (7) is completely freed from its resp. girdle (9) when the drive mirrors (7) teach the fire tube, it is known that the drive mirrors (7) are provided with external threads (8) on which resp. belts (9) provided with internal threads (8a) are threaded to resp. the foremost position of the external threads (8) in the projecting direction (a) of the projectile (6) and wherein these threads (8, 8a) are formed with a number of thread turns which is slightly less than the number of turns included in the barrel groove. 6. A method according to any one of claims 1 -4 to produce belted full caliber projectiles (1, l1 + 12) intended to be able to be fired from coiled tubing either completely rotationally free or with the rotation generated by the coiled tubing used in the firing, characterized in that the projectile is produced in the form of two projecting parts (11 and 12, 21 and 22, respectively) screwed together, of which one projectile part (12 and 22, respectively) has a joining part provided with an external thread (14 and 24, respectively) which is designed to be able to be inserted into a hollow provided with a corresponding internal thread (13 or 24a) provided therewith in the second projectile part (11 and 21, respectively) and wherein one of the projectile parts in connection with the joining between them has a turned-down and for threading it internally threaded belt (16 or 20) threaded portion (15 or 20a) on which the belt (16 or 20) is threaded before the projectile parts (11 and 12, 21 and 22, respectively) are screwed together . Belted projectile intended for the practice of the method according to any one of claims 1 - 6, characterized in that the belt (4,9,20) is connected to the projectile by means of its own internal thread (1 5a, 21a) and arranged along the outside of the projectile. corresponding external thread (15, 21), which threads (15a, 21a, 15, 21) cooperate with each other. Belted projectiles (1, l1 + 12) intended for the exercise of the method according to any one of claims 1 - 4, which projectiles (1, l1 + 12) can be fired completely without rotation, alternatively during the rotation that the barrel fox fl no one initiates, characterized each projectile (1, 11 + 12) comprises an external thread (3, 8, 15) on which, in itself an annular belt (4, 16), which in itself comprises a corresponding internal thread (15a), is threaded , and wherein these two threads (3, 8, 15, 15a) have the same thread direction as the barrel shaft and wherein the projectile's external thread (3, 8, 15) has such a thread pitch and thread length that it allows 10 15 20 529 751 1065 SE The belt (4a, 15a) adapted thereto with an internal thread (8a, 15a) to be displaced from a rear position in the projectile ejection direction (a) to the rear position (a) rear position of the projectile and that this movement comprises at least the number of thread turns corresponding to the number of turns so m barrel fox fl no one exhibits along the entire barrel. Belted projectile (6-9) intended for the exercise of the method according to any one of claims 1, 3 or 5 intended to be fired from a rifle fireball, which it shall leave completely without rotation due to the fact that the included saw is undercalibrated in its path towards the target fenstabilized armor-breaking arrow projectile (6), which is fired from the barrel in question by means of a drive mirror (7), which in turn has an external thread (8) on which the belt (9) with an internal thread (Sa) contained therein is threaded and wherein the thread (8) of the drive mirror (7) is adapted to its length so that the belt (9) leaves the drive mirror in connection with the projectile leaving the barrel. Belted projectile (6-9) - according to claim 9, characterized in that its belt (9) is provided with breaking instructions (10) which ensure that the belt (9) is broken into delar your parts in connection with it being threaded by propulsion mirror (7) and thus leaves the same.