DE102007052938B3 - Projectile with a swirl generating flow channels - Google Patents

Abstract

The invention relates to a projectile for firing from a smooth barrel or pipe with a swirl-generating flow channels in which the swirl-generating flow channels are arranged spirally in the shaft of a bullet core in the outer wall, the bullet core is rotatably mounted in a shell and the jacket openings for the Has outlet of the propellant gas leaving the bullet core from the barrel or pipe. In the rear end of the projectile a bushing with channels for the passage of the propellant gas and a valve for closing a provided in the bottom of the shell opening are arranged. The swirl-generating flow channels can also be arranged spirally in a guide pedestal in the outer wall, wherein the guide pedestal positively receives the projectile core and is rotatably mounted with the projectile core on a piston having channels for the passage of the propellant gas. At an initial speed of 1500 m / s to 1800 m / s and a stable flight, the projectile achieves a high firing range and penetrating power. It can be used for handguns as well as for guns and cannons.

Description

The The invention relates to a projectile with a swirl-generating flow channels. The Projectile is particularly suitable for firing from a smooth pipe.

To generate a twist of projectiles that are shot down from smooth pipes, it is z. B. from the US 5,164,538 A known to incorporate in the projectile surface at any inclination over the entire length of the projectile straight grooves or channels, which are flowed through by the propellant gases when shooting down.

In order to use the exploding power of the propellant gases more effectively, were with the DE 597633 B , Swirl channels proposed that expand again after a taper and a constriction, whereby the emerging from the constriction gas jet strikes a baffle and there undergoes a flow deflection, which is associated with an energy loss.

The goal is to develop a bullet that provides a ballistic flight adapted to the ballistic requirements of the projectile body and the spin is associated with the lowest possible losses, which reveal the DE 27 31 092 A1 and the DE 27 31 093 A1 Projectiles which are provided with swirl-generating flow channels, the inlet side a tapered part with subsequent constriction and then have an extension part, wherein the respective channel axis of the swirl ducts in the extension part rectilinear or moderately curved, skewed runs at a distance from the projectile axis. Compression collisions should be avoided by having the channel walls of the extension part, seen in the flow direction, a convex and / or straight shape and / or a maximum slightly concave curved shape. For this purpose, the flow channels can also be arranged in subcircular projectile bodies in spaced-apart guide rings whose outside diameter corresponds to the caliber of the tube or can be arranged in a cage surrounding the middle part of the projectile body. These guide means are separably attached to the projectile body. To stabilize the trajectory of the projectile sees the technical solution according to the DE 27 31 093 A1 to equip the rear end of the projectile body with a tail.

With the aim of improving the accuracy of the stabilizing swirl of said technical solutions, discloses US 4,249,465 A as a further development a stabilizer for a cannon projectile. The stabilizer consists of a one-piece solid cylindrical metal element with a first and different from this second diameter. The metal element is arranged coaxially at the rear end of the projectile and has a flat rear portion with a plurality of longitudinal axis-angled slots with parallel side walls. The air impinging on these side walls in the flight of the projectile should impart a spin to the projectile.

When problematic with this solution the limited Application on cannon projectiles and the relatively small range and accuracy to watch.

The US Pat. No. 3,065,696 A. and the US 3,225,694 A. show, then, Geschissen, whose flight is stabilized by generated spin.

task The invention is therefore a projectile of the aforementioned Art to improve so that it is independent of the caliber without additional Tail a high range of fire in a stabilized flight and has a high accuracy and penetration.

According to the invention Task by a bullet to shoot from a smooth run or pipe solved with a swirl-generating flow channels in which the swirl-generating Flow channels spiral in the Shaft of the projectile core are arranged in the outer wall, wherein the projectile core is rotatably mounted in a jacket, the jacket openings for the Outlet of the propellant gas leaving the projectile from the barrel or tube, in the rear end of the projectile a socket with a channel for the passage of the propellant gas and a valve for closing a provided in the bottom of the shell opening.

A embodiment The invention provides, the projectile core with his nose and his back End rotatable by means of axes and / or bearings within the shell to store.

According to others embodiments the invention, the valve is spring-loaded hinged to the socket and has the socket on a circumferential groove in the form-fitting bulbous trained section of the shell attacks.

According to further particular embodiments of the projectile according to the invention the opening for the exit of the propellant gases are arranged circumferentially equidistant from each other in the shell, the number of openings corresponding to the number of flow channels and the openings have a diameter, preferably the distance between the two side walls of a flow channel corresponds to the end in the flow direction to take.

in the The invention will be explained in more detail with reference to drawings. Show it

1 the longitudinal section through a projectile with a stored in a defect projectile core in the gun barrel;

2 the bullet according to 1 at the moment of leaving the gun barrel;

3 the cross section of the projectile according to 2 at the moment of leaving the gun barrel;

4 the excerpt I the 3 in an enlarged view;

5 the longitudinal section of a projectile after leaving the gun barrel;

6 the longitudinal section through the shell of the projectile according to the invention;

7 the side view of the projectile core;

8th the bottom view of the bullet core according to 7 ;

9 the section AA of the bullet core according to 7 ;

10 the projectile according to the invention with a closed valve;

11 Section I of the projectile according to 10 in an enlarged view;

12 the section BB of the projectile according to 10 ;

13 . 14 the detail II with a longitudinal section and a bottom view of a socket; according to 10 ;

15 the longitudinal section through another embodiment of an inventive projectile in a gun barrel;

16 the longitudinal section through a projectile according to 15 after ignition;

17 the side view of the projectile according to 16 ;

18 the section CC of the representation according to 17 ;

19 the longitudinal section through a projectile according to 15 when leaving the gun barrel; and

20 the representation of the bullet core with the originally associated with him components.

1 shows a projectile according to the invention after ignition. The bullet is still in the cartridge 19 , Inside the coat 3 is the bullet core 2 by means of the axes 6 rotatably mounted. The coat 3 is preferably made of steel. At the end of the tapered part of the bullet core 2 is in the coat 3 the socket 5 with the spring-loaded valve 7 arranged. The socket 5 has the passageways 9 on. The valve 7 is used to open and close the bottom of the jacket 3 provided opening 11 , As 13 shows, owns the socket 5 a circumferential groove in the form-fitting a bead-shaped portion of the shell 3 attacks. It can be clearly seen that the bullet core 2 in its conical and its rear cylindrical portion spirally arranged flow channels 4 having.

After the ignition of the charge - like 1 and 2 show - expands the expanding propellant gases against the spring-loaded valve 7 that in the bottom of the coat 3 located opening 11 releases. Through the passageways 9 according to 14 at a uniform distance from each other in the socket 5 are arranged radially, the propellant gas penetrates into the spirally arranged flow channels 4 of the projectile core 2 and the space formed by a gap between the bullet core 4 and the coat 3 and there generates the pressure G.

How out 6 it can be seen has the coat 3 on its circumference in a uniform spaced openings 10 for the escape of the propellant gas when the bullet core 2 the pipe 1 leaves ( 3 ). The openings 10 are preferably formed and arranged so that they the course of the spirally arranged flow channels 4 continue. The number of openings 10 corresponds to the number of flow channels 4 , The diameter of the openings 10 preferably corresponds to the distance, the two side walls of a flow channel 4 take each other at the end in the direction of firing. The moment the projectile reaches the gun barrel 1 leaves, the openings become 10 released and flow the compressed propellant gases flow channels 4 along in the atmosphere, at the same time closes the valve 7 the opening 11 , like out 5 is apparent. At the moment of the outflow of propellant gases and after closing the opening 11 the propellant flows with the force F through the flow channels 4 and practice on them lateral pressure P off ( 4 ), the rotatably mounted bullet core 2 inside the coat 3 gives a twist. In a gas-dynamic manner, the torque M is thus generated ( 3 ). Depending on which pressure G between the bullet core 2 and the coat 3 created and depending on which lateral pressure P in the flow channels 4 must be exercised around the bullet core 2 To achieve the necessary rotational speed, the number and diameter of the passageways 9 be chosen differently. As the bullet core 2 in the coat 3 rotatably mounted, not only a very high rotational speed of this bullet core can be 2 reach, but at the same time receives the projectile required for high accuracy high stability. Because at the moment of the exit of the propellant gas from the openings 10 of the coat 3 the valve 7 at the bottom of the mantle 3 located opening 11 closes, lend the continuing acting propellant gases leaving the smooth run 1 A gun or tube of a gun fired projectile a particularly high initial speed of 1500 m / s to 1800 m / s and a higher firing range over the known prior art solutions.

15 shows a particular embodiment of a projectile according to the invention. This bullet is the bullet core 12 positively in a guide base 15 stored. In the outer wall of the guide pedestal 15 are - as well as out 17 it can be seen - the flow channels 13 arranged spirally. The guide pedestal 15 preferably consists of a wear-resistant and high-temperature resistant plastic and may have predetermined breaking points. The guide pedestal 15 is with the help of the camp 14 rotatable on the cup-shaped piston 16 stored, for the passage of the propellant gases the channels 17 having. The surrounding in the direction of the cartridge case or cartridge wall 20 of the piston 16 has the paragraph at its end 21 on, with which the piston 16 is mounted on the cartridge case or the cartridge. The channels 17 are preferably radially equidistant from each other in the piston 16 arranged. After ignition of the charge, the developing propellant gases pass through the channels 17 and practice with the force F the pressure P laterally on the flow channels 13 of the guide pedestal 15 out ( 17 . 18 ). In particular, the bottom of the bullet core 2 and the inside of the bottom of the guide pedestal 15 have a complementary trained profile, which ensures that the bullet core 2 by the pilot base set in rotation with the propellant gases 15 lossless receives the same rotational speed as the guide pedestal 15 , If necessary, it is sufficient to the bottom of the bullet core 2 and the inner surface of the guide pedestal 15 to give a corresponding roughness. The warehouse 14 makes it possible to keep the energy losses due to the friction to be overcome during the rotation as low as possible.

19 and 20 show that after leaving the projectile from the gun barrel 1 the guide pedestal 15 , the warehouse 14 and the cup-shaped piston 16 by the resistance of the air flow and possibly existing predetermined breaking points sliding from the projectile core 2 solved by the gas-dynamically generated spin and the smooth barrel / gun barrel 1 Achieved a particularly high rotational and initial speed and accuracy in stable flight.

Furthermore, it is a particular advantage of the projectile according to the invention that it can be used for handguns as well as for guns or cannons with a caliber of up to 150 mm. The smooth run 1 or the smooth tube 1 In addition, in comparison to drawn barrels or pipes, they can also be produced more efficiently and, with considerable material effects, can also be made more thin-walled.

1

run or pipe

2

bullet core

3

coat

4

flow channel

5

Rifle

6

Camp, axes

7

Valve

8th

feather

9

Duch passageway

10

opening

11

opening

12

bullet core

13

flow channel

14

camp

15

Leadership pedestal

16

piston

17

channel

18

Side wall

19

Sleeve or cartridge

20

edge

21

paragraph

22

Sleeve or cartridge

F

force

G

print

M

torque

P

print

Claims (6)

Projectile for firing from a smooth barrel or pipe ( 1 ) with a swirl-generating flow channels ( 4 ; 13 ), characterized that the swirl-generating flow channels ( 4 ) spirally in the shaft of a projectile core ( 2 ) are arranged in the outer wall, the projectile core ( 2 ) in a jacket ( 3 ) is rotatably mounted and the jacket ( 3 ) Openings ( 10 ) for the exit of the propellant gas leaving the bullet core ( 2 ) from the barrel or tube ( 1 ) and in the rear end of the projectile a bushing ( 5 ) with a channel ( 9 ) for the passage of the propellant gas and a valve ( 7 ) for closing one in the bottom of the shell ( 3 ) opening ( 11 ) are arranged. Projectile according to claim 1, characterized in that the projectile core ( 2 ) with its nose and its rear end by means of axles or bearings ( 6 ) within the coat ( 3 ) is rotatably mounted. Projectile according to claim 1 or 2, characterized in that the valve ( 7 ) spring-loaded on the bushing ( 5 ) is articulated. Projectile according to one of claims 1 to 3, characterized in that the bushing ( 5 ) has a circumferential groove in the form-fitting a bead-shaped portion of the shell ( 3 ) attacks. Projectile according to one of claims 1 to 4, characterized in that the openings ( 10 ) for the exit of the propellant gases circumferentially at the same distance from each other in the shell ( 3 ) are arranged in a number corresponding to the number of flow channels ( 4 ) corresponds. Projectile according to one of claims 1 to 4 or 9, characterized in that the openings ( 10 ) in the coat ( 3 ) have a diameter, preferably the distance between the two side walls ( 18 ) of the flow channel ( 4 ), which they occupy at the end in the direction of firing.