EP3637039A1 - Carrier projectile for a gun - Google Patents

Abstract

A carrier projectile (2) for a barrel weapon (20) with a barrel (22) which extends along a central longitudinal axis (4) contains a floor (8), a casing (14) which is in an initial state (A) with the Floor (8) is connected, and which is releasable in an axial direction away from the floor (8) when a release force (L) acts between the floor (8) and the casing (14) in the axial direction, which exceeds a limit force (G), whereby the floor (8) and the casing (14) enclose a receiving space (16) for a payload (17), and a separating device (18), the release force (L) from the separating device (18) after leaving the barrel (22) is generated without using an exhaust charge and / or without using an igniter.

Description

The invention relates to a carrier bullet for a barrel weapon.

Such a main storey is, for example, the widespread "SMArt 155" storey from GIWS mbH. The projectile uses a time fuse and an ejection charge (usually pyrotechnics) to pyrotechnically discharge a payload / submunition from the projectile after a defined point in time. Other known bullets are, for example, the "40mm M1001 HVCC" from General Dynamics (Flechet Munition) or classic shot ammunition, which is fired from smooth barrel weapons.

The object of the invention is to provide an improved support bullet for a barrel weapon.

The object is achieved by a carrier bullet according to claim 1 for a barrel weapon with a barrel. Preferred or advantageous embodiments of the invention and other categories of invention result from the further claims, the following description and the attached figures.

The main floor extends along one or its central longitudinal axis. The main floor contains a floor and in particular a guide band. The guide band is usually arranged on the peripheral surface of the floor. The circumferential surface or direction relates to the central longitudinal axis. The peripheral surface thus points radially outward with respect to the central longitudinal axis. The central longitudinal axis represents an axial direction of the carrier projectile. The projectile is also assigned a designated launch or flight direction after firing from the barrel weapon, which is directed in the axial direction.

The main storey contains a shell which is connected to the floor of the storey in an initial state. The initial state is the intended state of the main floor between its manufacture and its launch. The cover can be removed in the axial direction away from the floor of the storey. The release takes place only if there is an axial release force between the floor and the shell (or two opposing forces: counter on the floor and on the shell in the direction of flight) that exceeds a limit force. The floor and the envelope enclose a receiving space for a payload. The carrier floor contains a separating device for generating the release force. The release force is or is generated by the separating device after leaving the barrel without using an ejection charge and / or without using an igniter.

The optional guide band seals the floor of the floor from the barrel when inserting or using the carrier bullet in a designated barrel weapon. With regard to the intended firing direction or flight direction, the floor forms the rear part, the shell the front part of the carrier floor. In other words, the carrier projectile works without pyrotechnics and / or without stored chemical energy and / or without a timer. Construction fragments, flechets or other active elements or active agents or effectors, for example, come into consideration as the payload.

As long as the carrier bullet is still in the barrel of the barrel weapon after the shot, the shell remains connected to the bullet floor. Only after leaving the barrel are the shell and the floor of the floor separated from one another by applying the release force. In the initial state or in a holding state (which continues even after the shot has been fired until the casing and base have separated), the floor and the shell are fastened or held to one another by means of a connecting means.

In a preferred embodiment of the invention, the release force is or is generated - in particular exclusively - aerodynamically on the carrier floor during the flight of the carrier floor. The release force is thus generated by the air that surrounds or is flown through by the fired and flying projectile. In this regard, no additional aids (detonator, exhaust charge, ...) are required to generate the release force. Since appropriate aerodynamics and thus the release force only occurs when the carrier bullet has left the barrel of the barrel weapon, this ensures that the shell and Do not detach the floor of the floor from one another while the weapon is still in motion and thus undesired release of the payload occurs. In this regard, the supporting floor is designed to be particularly secure. The separating device is therefore operated or designed aerodynamically.

In a preferred variant of this embodiment, the release force is - or is exclusively - generated by air pressure. The "air pressure" is pneumatic pressure which is generated by the air flowing in on the carrier floor during flight and which is or is generated aerodynamically by the flight of the carrier floor. The pressure can be positive (positive pressure, thrust) or negative (suction, negative pressure) as a relative pressure to a reference pressure on the projectile. The separating device is then - in particular exclusively - operated by this pneumatic or air pressure device. Pneumatic or air pressure can be used particularly easily, reliably and safely within the carrier floor.

In a preferred variant of this embodiment, the separating device contains an opening in the casing. During the flight, the opening is exposed to a dynamic pressure or air pressure. Due to the dynamic pressure, an overpressure in the form of air pressure is or is generated in the receiving space by means of the opening. Air flows into the carrier floor or into the receiving space through the opening during the intended flight of the carrier floor. As a result, the excess pressure is generated in the receiving space. The overpressure acts on the floor and shell and causes opposing axial forces on both elements, which endeavor to separate the two elements from one another in the axial direction or to push them apart. In this case, in particular, the limit force is smaller than the release force generated by the excess pressure. At least the force generated by the overpressure contributes to the release force.

In a preferred variant of this embodiment, the opening is located at that end of the casing which points forward in the intended direction of flight, that is to say at the front end or the tip of the casing. Incoming air can be absorbed particularly well there or the above-mentioned dynamic pressure can be generated.

In a preferred variant of this embodiment, the separating device contains a filling element which closes the opening in the initial state. Thus in Initial state, the opening and thus also the recording room and the supporting floor as a whole are protected from undesired foreign substances (dust, dirt, moisture) penetrating through the opening. To open the opening, the filling element must be removed at the latest when it is desired to allow air to flow into the opening. This is particularly the time when the carrier bullet leaves the barrel of the barrel weapon after firing. The filling element can be implemented in any way, for. B. starting with a wax, wood, metal or plastic plug, up to a part of the shell that z. B. can be separated from the rest of the shell by a predetermined breaking point in order to open the opening.

The filling element can in particular before firing the carrier floor - z. B. by hand - can be removed, for example during or shortly before loading the barrel weapon. Alternatively, the filling element can also be designed in such a way that it is automatically removed when the carrier projectile is fired.

In a preferred variant of this embodiment, the filling element can therefore be removed from the opening or is removed in this way by a firing shock that occurs when the projectile is fired. Filling element and / or opening are therefore appropriately dimensioned or matched to one another to ensure removal during the launch shock. For example, a corresponding holding force of the filling element in the opening or a breaking force of a corresponding connection or of the filling element itself is dimensioned in such a way that the holding force is less than the force which acts in the event of a designated launch shock. The releasing force is generated by the inertia of the filling element. An automatic removal of the filling element can thus be implemented particularly easily.

In a preferred variant of the above-mentioned embodiment, the separating device contains a surface arranged on the floor. The surface is exposed to an aerodynamically generated suction force by the passing air during the flight of the carrier floor. The suction force is directed away from the casing against the direction of flight. Since the shell itself strives to continue flying in the direction of flight, the suction force causes at least part of the release force. In particular, the suction force is added together with the above-mentioned force generated by the excess pressure in the receiving space to the total release force. In this way, the release force can be generated particularly effectively and easily. In particular, the area is the floor area of the floor that is directed backwards with respect to the flight direction.

In a preferred embodiment of the invention, the floor and the casing are held together in the initial state by a frictional and / or positive connection or a corresponding connecting means. The connection can be released when the release force is applied (greater than / equal to the limit force). As soon as the limit force is applied, the corresponding connection is released or is subsequently released. In particular, an adhesive force and / or holding force of the connection which is correspondingly brought about by the connection is dimensioned less than or equal to the limit force. The connection is dimensioned accordingly with regard to the forces. The corresponding connection is thus at least part of the above-mentioned connection means. In particular, the connecting means is or contains a compressible sealing element which requires the application of at least the limiting force in order to compress and overcome a frictional / positive connection. Alternative connecting means or parts thereof are, for example, adhesive or press connections, predetermined breaking points, tear seams, etc.

In a preferred embodiment of the invention, the carrier bullet is a carrier bullet for a barrel weapon with a drawn barrel. The optional guide belt is then one for the swirl transmission from the barrel to the carrier floor. Thus, the carrier bullet is suitable for the majority of available barrel weapons. In addition, the general advantages of a swirl also result for the present carrier floor.

In a preferred variant of this embodiment, the carrier projectile has a swirl transmission element. The swirl transmission element is arranged in the receiving space and fastened to the floor and / or to the shell and at least partially penetrates the receiving space for the payload for swirl transmission. The enforcement extends so far that a intended payload is subjected to the twist in the desired manner. Swirl that is transmitted from the barrel of the barrel weapon to the carrier projectile is also transmitted to the payload by means of the swirl transmission element. The swirl transmission element is in particular a driving element that is connected in a rotationally fixed manner to the floor of the floor and or the casing with respect to the central longitudinal axis. For example, grids, brackets, pins etc. are conceivable as a driving element

In a preferred variant of this embodiment, the swirl transmission element contains or is at least one wall that extends at least partially through the receiving space. So the recording room is at least at the divided into two parts per wall. Each subspace can then accommodate at least part of the payload. The swirl transmission then takes place by contacting the wall. In particular, the swirl transmission element contains two cross-sectionally arranged walls that intersect on the central longitudinal axis of the supporting floor. The wall is designed in particular with or without cutouts. In particular, the wall is attached to the floor of the floor. This creates simple options for swirl transmission to the payload.

In a preferred variant of the above-mentioned embodiment, which represents in particular an alternative to the swirl transmission element, the carrier projectile contains a swirl decoupling element for receiving at least a part of the payload. The swirl decoupling element is decoupled from the floor of the floor and the casing with respect to a rotation about the central longitudinal axis. The rest of the carrier level can therefore perform a swirl movement without the swirl decoupling element (and the payload contained therein) following it. It is thus possible to orient the payload or its relevant part on the swirl decoupling element and thus to decouple swirl from the swirling part of the supporting floor, in particular from the floor and the shell. These elements then have no swirl. The advantages of a swirling carrier bullet are retained without having to subject the payload to a swirl.

In a preferred variant of this embodiment, the swirl decoupling element contains or is a receiving body for at least part, in particular the entire payload. The receptacle is rotatably mounted in the floor and in the envelope around the central longitudinal axis. Since the receiving body itself is spin-decoupled, the entire payload held in it is also spin-decoupled. The receiving body is in particular a tub, cup or pot, the opening of which points in particular in the direction of flight and which is in particular axially symmetrical to the central longitudinal axis. With regard to the acceleration of the carrier projectile, the payload is therefore in contact with a floor of the receiving body that points counter to the direction of flight. The swirl decoupling can be accomplished particularly easily in this way.

The invention is based on the following findings, observations and considerations and also has the following embodiments. The embodiments are sometimes also called "the invention" for simplicity. The Embodiments may also include or correspond to parts or combinations of the above-mentioned embodiments and / or possibly include embodiments not previously mentioned.

The invention is based on the basic idea of designing a carrier system for barrel weapons (with a drawn barrel / twist) in order to spend a payload (construction splinters, flechets, other active elements) from a drawn barrel. At the same time, disassembly in the run should be excluded.

The invention is based on the basic idea that the projectile (in the axial direction) is created by the suction on the floor (which arises aerodynamically during flight) and an air inlet which (also aerodynamically during flight) creates an overpressure in the interior of the floor (receiving space). to pull apart and open (to separate the shell from the floor).

Compared to classic cargo projectiles with a time fuse and exhaust charge, the carrier projectile according to the invention does not require an expensive time fuse with pyrotechnics and can also be used in particular in small calibers (medium caliber, .50 / 12.7 mm or larger). Furthermore, no chemical energy is stored in the floor itself, which completely avoids the danger from explosives. The question of IM properties (insensitive ammunition) does not arise in the first place. Premature opening and disassembly during the run is technically impossible. This is due to the fact that the opening of the projectile can only be accomplished by dynamic processes during the flight; in contrast, pressure is exerted on a solid floor (floor) during the run. It is technically impossible for bullet parts to remain in the barrel.

According to the invention, it is possible to spend active agents (for example splinters or flechets) from a drawn barrel without opening the carrier projectile and releasing the active agents in the barrel. The invention allows implementation without having to resort to an (expensive) igniter or other unlocking devices. The invention also allows implementation without having to store chemical energy. This leads to an advantage in IM questions, chemical compatibility, storage stability and storage group classification.

According to the invention, the payload is released immediately after the run (0-5m, in particular 0.5-3m, in particular 1-2m). The carrier system (carrier bullet) enables the transfer, similar to shot or can ammunition from drawn barrels, with simultaneous (optional) swirl transfer to the payload.

The carrier floor is accelerated in one run like a classic floor. In the case of a drawn barrel, the twist is transmitted through the guide belt. The pressure exerted on the rear of the projectile accelerates it and opens the sealed air inlet (opening with filler element) (removal of the filler element from the opening by means of a launch shock). In the following flight phase (after leaving the run) the acceleration force at the rear is eliminated and is replaced by a suction (caused by the air flowing past). At the same time, the air flowing in (through the opening / air inlet) creates overpressure in the interior of the floor (receiving space). Suction and overpressure ensure that the floor opens (separation of floor and shell). Due to the accelerating force in the barrel, the bullet cannot be disassembled in the barrel.

If swirl transmission to the payload is desired, an optional swirl transmission system (swirl transmission element) can be used. One reason for a desired swirl transmission to the payload would be a larger fanning out of the payload (usually effectors) in order to enlarge the effective range (conical in front of the muzzle).

If swirl transmission is not desired in order to stretch the effective area and work more deeply, the swirl transmission element can be replaced. In this case, a rotatable trough (receiving body) is used in the floor, in which the payload is twist-decoupled.

According to the invention it is therefore possible to transfer swirl to the payload or to decouple it from the swirl.

Figur 1

ein Trägergeschoss in a) Außenansicht und b) im Querschnitt (Linie Ib-Ib in Fig. 1a),

Figur 2

eine Darstellung der Funktionsweise des Trägergeschosses aus Figur 1 in den Phasen a) Abschuss, b) Flug und c) Öffnung (Darstellung gemäß Fig. 1b),

Figur 3

den Geschossboden des Trägergeschosses aus Figur 1 mit Drallübertragungselement a) im Schnitt gemäß Fig. 1b und b) in Draufsicht entgegen der Richtung des Pfeils 6 in Fig. 3a,

Figur 4

den Geschossboden des Trägergeschosses aus Figur 1 mit Drallentkopplungselement im Schnitt gemäß Fig. 1b.

Further features, effects and advantages of the invention result from the following description of a preferred exemplary embodiment of the invention and the attached figures. A schematic diagram shows:

Figure 1

a carrier floor in a) exterior view and b) in cross section (line Ib-Ib in Fig. 1a ),

Figure 2

a representation of the mode of operation of the supporting floor Figure 1 in phases a) launch, b) flight and c) opening (presentation according to Fig. 1b ),

Figure 3

the floor of the main floor Figure 1 with swirl transmission element a) in section according 1b and b ) in plan view against the direction of arrow 6 in Fig. 3a ,

Figure 4

the floor of the main floor Figure 1 with swirl decoupling element in section according Fig. 1b .

Figure 1 shows an inventive carrier floor 2 for an in Figure 2a indicated barrel weapon 20. The carrier bullet 2 extends along a central longitudinal axis 4, which describes an axial direction of the carrier bullet 2. The carrier projectile 2 also has an intended direction of flight 6 (indicated by an arrow), which is directed in the direction of the central longitudinal axis 4. The carrier projectile 2 contains a storey floor 8. A guide band 12 is arranged on the storey floor 8 on a circumferential surface 10 pointing radially outward (with respect to the central longitudinal axis 4 or axial direction).

The carrier floor 2 also contains a shell 14 in the form of an upper shell, which in the Figure 1 initial state A shown is connected to the floor 8. Floor 8 and casing 14 can, however, be detached from one another in the axial direction by moving the casing 14 in the direction of flight 6 and / or the floor 8 opposite to the direction of flight 6 (consideration of the relative movements). For this purpose, the application of a loosening force L, only indicated in the figures, between the floor 8 and the casing 14 (acts on both elements in opposite directions) is necessary for the movement described above. The loosening force L must be greater than a limit force G up to which the floor 8 and the shell 14 hold together. In the example, the floor 8 and the envelope 14 are in one Figure 1b only symbolically indicated friction-locking / positive-locking connection 36 is held together, which is released when a release force L is applied greater than or equal to the limit force G. The corresponding frictional locking / positive locking elements (not shown) therefore form a connecting means 37 in order to hold the shell 14 and floor 8 against one another until the limiting force G acts.

Floor 8 and casing 14 surround a receiving space 16 in the interior of the supporting floor 2. In the receiving space 16, the supporting floor 2 conveys a payload 17, which is only symbolically indicated here, here construction splinters.

The carrier bullet 2 contains a separating device 18. When the carrier bullet 2 is used as intended, ie after it has been fired and during its flight, namely after leaving one in Figure 2a barrel 22 of the barrel weapon 20 shown, the separating device 18 generates the release force L, which finally becomes greater than or equal to the limit force G. The generation takes place here without using an exhaust charge and without using an igniter (both of course therefore not shown).

The separating device 18 contains an opening 24 in the casing 14. The casing 14 is therefore pierced by the opening 24, which forms an air inlet opening, as will be explained later. The opening 24 is located at that end 26 of the carrier projectile 2 or the casing 14 which is at the front with respect to the direction of flight 6. Here, the opening 24 is located at the tip 28 of the carrier storey 2 or the casing 14.

In Figure 1a, b the opening 24 is closed by a filling element 30. However, the filler 30 is removable from the opening 24 to expose it, as will be explained later. In the initial state A, the opening 24 is therefore a sealed air inlet opening.

The separating device 18 further includes a surface 32 which is arranged on the floor 8. Here, the surface 32 is formed by the end 34 of the carrier floor 2 or the floor 8, which is opposite the end 26 or the tip 28 with respect to the direction of flight 6.

The guide band 12 serves to seal the carrier floor 2 or the floor 8 against the barrel 22 or the inside thereof. The barrel 22 is a drawn barrel 22. The guide band 12 is therefore also used for the swirl transmission from the barrel 22 to the floor 8 and thus the entire supporting floor 2.

The operation of the support level 2 is explained as follows:
When it is used, the carrier bullet 2 is inserted into the barrel weapon 20 or its barrel 22 and fired in a conventional manner. Figure 2a shows the carrier projectile 2 as it passes through barrel 22 after the launch.

During this firing process in barrel 22, the carrier projectile 2 is accelerated by a drive (propellant charge), which is not shown in detail. The drive or the acceleration force is symbolized by an arrow 38. The corresponding force acts on the floor 8 or the surface 32 or the end 34 and acts in the direction of the flight direction 6. At the same time the sealed air inlet opening (opening 24, closed by the filling element 30) is opened inwards by the launch shock: the Filling element 30 is thus released from the opening 24 by means of its inertia and conveyed in the direction of arrow 40 into the receiving space 16. If the carrier projectile 2 leaves the muzzle opening of the barrel 22, not shown, the drive or the acceleration of the carrier projectile 2 ends.

Figure 2b shows the now following flight phase of the carrier projectile 2 in the air 40. In the flight after leaving the barrel 22, the acceleration (arrow 38 in Figure 2a ) on floor 8 no longer. Instead, air 40, which is traversed by the carrier floor 2, creates a suction on the floor 8 due to the aerodynamics, which causes a force against the flight direction 6 on the floor 8. The corresponding force is indicated by an arrow 42. The corresponding suction thus acts counter to the direction of flight 6. The sleeve 14, on the other hand, endeavors to move less or unchecked in the direction of flight 6. Already due to the corresponding suction and the inertia of the casing 14, a part of the release force L is created, which tends to separate the casing 14 and the floor 8 from or in the opposite direction of flight 6.

At the same time, a second effect takes place: through the opening 24 or air inlet opening (indicated by the arrow 44), air 40 flows into the receiving space 16 or interior of the carrier floor 2. In other words, due to the aerodynamics, a corresponding dynamic pressure builds up in the receiving space 16 that exceeds the ambient pressure. This creates an overpressure in the carrier level 2 or receiving space 16 with respect to the surrounding air 40. This back pressure or overpressure also causes part of the release force L. In the example, the release force L is composed precisely of the two components mentioned (suction and back pressure).

Figure 2c shows the corresponding relationships: The total release force L, symbolized here by a double arrow, is greater than the limit force G and therefore leads to the sheath 14 and the floor 8 being detached from one another in or against the direction of flight 6. The receiving space 16 or the supporting floor 2 is thereby opened and the payload 17 located therein is released. In other words, the resulting force (release force L) from suction (arrow 42) and internal pressure (arrow 44) is greater than the force that the connecting means 37 can hold in the form of the connection 36. Payload 17, which is still in the casing 14 after the separation of the casing 14 and the floor 8, is also pressed out of the casing 14 by the air flowing in through the opening 24. The floor 8 drops due to the suction on the surface 32 anyway from the payload 17.

Figure 3 shows part of an alternative supporting floor 2. This contains the floor 8 from Figure 1 who in 3 a) in sectional side view according to Figure 1b and in Fig. 3b ) is shown in plan view against the direction of flight 6. In the floor 8, a swirl transmission element 50 (in the form of a support element) of the support floor 2 is fastened or fixedly connected to the floor 8. The swirl transmission element 50 serves to transmit a swirl, which the floor 8 has, to the payload 17. The swirl transmission element 50 extends over a part of the receiving space 16 and therefore interacts with the payload 17 located therein by positive locking, as in FIG Figure 3b ) is indicated. The swirl transmission element 50 here consists of two walls 52, which each extend along the central longitudinal axis 4 and are rotated by 90 ° relative to one another, so that they form a cross structure in cross section.

Figure 4 shows an alternative embodiment of the supporting floor 2. This also contains the floor 8 according to Figure 1 . However, a swirl decoupling element 54 is arranged in the floor 8. With respect to the central longitudinal axis 4 or the axial direction, the floor 8 and the swirl decoupling element 54 can be rotated relative to one another and thus decoupled from one another with respect to this rotation. The swirl decoupling element 54 serves to accommodate the payload 17, which is indicated here in the form of flechets. The swirl decoupling element 54 thus forms a receiving body 56, here in the form of a cup-shaped circular cup which is open in the direction of flight 6. The swirl decoupling element 54 can thus be rotated about the central longitudinal axis 4 or axial direction with respect to the entire supporting floor 2 both in the floor 8 and in the casing 14. In the event of a swirl transmission from barrel 22 to carrier level 2, swirl decoupling element 54 retains together with the payload 17 due to the rotational inertia, its rotational rest position about the central longitudinal axis 4. In other words, the cup and the payload 17 “slip” relative to the floor 8 and the casing 14 about the central longitudinal axis 4 or axial direction “through”.

Reference list

2nd

Carrier floor

4th

Central longitudinal axis

6

Flight direction

8th

Floor

10th

Circumferential surface

12th

Guide band

14

Cover

16

Recording room

17th

payload

18th

Separator

20th

Barrel weapon

22

Run

24th

opening

26

The End

28

top

30th

Filling element

32

surface

34

The End

36

connection

37

Lanyard

38

arrow

40

air

42

arrow

44

arrow

50

Swirl transmission element

52

wall

54

Swirl decoupling element

56

Receiving body

A

Initial state

L

Dissolving power

G

Limit force

Claims (14)

Carrier projectile (2) for a barrel weapon (20) with a barrel (22) which extends along a central longitudinal axis (4), - with one floor (8), - With a casing (14) which is connected to the floor (8) in an initial state (A) and which is detachable in an axial direction away from the floor (8) if a release force (L) between the floor (8 ) and sleeve (14) acts which exceeds a limit force (G), - The floor (8) and the casing (14) enclosing a receiving space (16) for a payload (17), - And with a separating device (18), the release force (L) of the separating device (18) after leaving the barrel (22) is generated without using an exhaust charge and / or without using an igniter. Carrier projectile (2) according to claim 1,
characterized,
that the release force (L) is generated aerodynamically on the carrier floor (2) during the flight of the carrier floor (2). Carrier projectile (2) according to claim 2,
characterized,
that the release force (L) is generated by air pressure generated by the flight. Carrier projectile (2) according to claim 3,
characterized,
that the separating device (18) contains an opening (24) in the casing (14) which is exposed to a back pressure of inflowing air during flight, the back pressure creating an overpressure in the form of air pressure in the receiving space (16). Carrier projectile (2) according to claim 4,
characterized,
that the opening (24) is located at the front end (26) of the casing (14) pointing in the direction of flight (6). Carrier projectile (2) according to claim 4 or 5,
characterized,
that the separating device (18) contains a filling element (30) closing the opening (24) in the initial state (A). Carrier projectile (2) according to claim 6,
characterized,
that the filling element (30) can be removed from the opening (24) by a launch shock occurring when the projectile (2) is fired. Carrier projectile (2) according to one of Claims 2 to 7,
characterized,
that the separating device (18) contains a surface (32) which is arranged on the floor (8) and which is exposed to a suction force during the flight due to air flowing past, the suction force being directed away from the casing (14) against the direction of flight (6). Carrier projectile (2) according to one of the preceding claims,
characterized,
that the floor (8) and the casing (14) are held together in the initial state (A) by a frictional and / or positive connection (36) which can be released when the limiting force (G) is applied. Carrier projectile (2) according to one of the preceding claims,
characterized,
that the carrier bullet (2) is a carrier bullet (2) for a barrel weapon (20) with a drawn barrel (22). Carrier projectile (2) according to claim 10,
characterized,
that the carrier projectile (2) in the receiving space (16) has a swirl transmission element (50) which is on the floor (8) and / or the sleeve (14) is fastened and at least partially passes through the receiving space (16) for swirl transmission. Carrier projectile (2) according to claim 11,
characterized,
that the swirl transmission element (50) contains or is at least one wall (52) extending at least partially through the receiving space (16). Carrier projectile (2) according to one of Claims 10 to 12,
characterized,
that the carrier projectile (2) contains a swirl decoupling element (54) for receiving at least a part of the payload (17), the swirl decoupling element (54) decoupling from the floor of the floor (8) and the casing (14) with respect to a rotation about the central longitudinal axis (4) is. Carrier projectile (2) according to claim 13,
characterized,
that the swirl decoupling element (54) contains a receiving body (56) for at least part of the payload (17), which can be rotated in the floor (8) and in the casing (14) about the central longitudinal axis (4).

Images