CN113028895A - Method for shooting shell-less bullet - Google Patents

Abstract

The invention relates to a method for launching a shell-less bullet, which comprises a stator (1), a turntable (6), a cartridge clip box (11), a cartridge clip (12), a gun handle (13) and a gun seat. The kinetic energy of the bullet (14) is transferred from the kinetic energy of the turntable (6), so that the launching of the shell-less bullet becomes possible, the pollution to the environment and the harm to fighters caused by gunpowder explosion are eliminated, the heat generation of the gun barrel is delayed, and the potential safety hazard of bullet storage and transportation is eliminated; if the rotating speed of the rotating disc (6) is s revolutions per minute, the number of the shot (14) shot per minute is 2ns, and the intensive shooting of the shell-free bullets is realized; the two gun barrels (5) can simultaneously launch the shots (14), so that the combat performance is greatly improved; the hot weapon of the invention returns to the cold weapon, and the return is not a retrogression, but a larger technical progress of the weapon, the significance of the invention exceeds the technical progress of the cold weapon developing into the hot weapon before hundreds of years, and the invention can possibly generate a far-reaching influence.

Description

Method for shooting shell-less bullet

Technical Field

The invention relates to a method for shooting a shell-free bullet, in particular to a method for shooting the shell-free bullet, which can intensively shoot the shell-free bullet at high speed.

Background

Shell bullets are commonly used in current firearms. The bullet is provided with the shell, firstly, the shell is used for containing gunpowder, secondly, the gunpowder can generate large thrust to the bullet when the gunpowder explodes in the shell with small volume, so that the bullet obtains large kinetic energy, and thirdly, the gun and soldiers are protected. Firearms are currently a revolutionary technological advance over cold weapons.

But the shell bullet has defects.

Firstly, the shot is shot one time, the shooting speed is low, but the current weapon is developed quickly, and the weapon can not be used for reverse guidance.

Secondly, the temperature of the firearms is quickly raised due to the explosion of gunpowder, the shooting precision is reduced, the speed of the projectile outlet is reduced, the soldiers operate the firearms to hurt the hands, and the firearms cannot be used for a long time.

Thirdly, the gunpowder explosion pollutes the environment and harms the physical health of the soldiers.

Fourthly, the storage or transportation of the shell bomb has great potential safety hazard.

In order to eliminate the above drawbacks, innovations in firearms and caseed cartridges currently using caseed cartridges are needed.

Disclosure of Invention

The invention aims to provide a method for shooting a shell-free bullet, which can intensively shoot the shell-free bullet at high speed.

In order to solve the technical problem, the technical scheme of the invention is as follows:

a method for shooting a non-shell bullet comprises a stator, a rotary disc, a bullet clip box, a bullet clip, a gun handle and a gun seat.

The stator comprises a cylinder, a side plate, a rotating shaft and a gun barrel.

The side plate is a vertical thick circular plate, the inner lateral surface of the side plate is smooth, and the lower part of the side plate is provided with a rectangular hole through which the projectile can transversely pass.

The cylinder has a thick cylinder wall, the axis of the cylinder is horizontal, the outer diameter of the cylinder is equal to the outer diameter of the side plate, two end faces of the cylinder are respectively and fixedly connected with the inner lateral faces of the two side plates at corresponding positions, the axis of the cylinder is coincident with the axes of the two side plates, the cylinder is made of high-strength wear-resistant materials, the inner circumferential surface of the cylinder is smooth, two horizontal round holes are tangentially arranged on the cylinder wall at the upper part of the cylinder, and two inclined smooth slideways which can allow the shots to pass through are also arranged on the cylinder wall at the upper part of; the two round holes are divided at two sides of the cylinder and are parallel to each other; the two slide ways are arranged on two sides of the cylinder and are symmetrical with each other; the slide way on any side of the cylinder has an inlet on the inner circumferential surface of the corresponding side of the cylinder and an outlet connected with the rear end of the circular hole on the corresponding side.

The barrel has an outer diameter greater than the inner diameter of the cylindrical bore and a bore through which the projectile passes.

The rear ends of the two gun pipes are forcibly inserted into the two round holes on the cylinder in a tight fit mode respectively, the front ends of the two gun pipes horizontally extend forwards, and the rear ports of the upper chambers of the two gun pipes are smoothly communicated with the outlets of the two slide ways respectively.

The two ends of the rotating shaft respectively pass through the shaft holes on the two side plates and are respectively fixedly connected with the two side plates, and the axis of the rotating shaft is superposed with the axes of the two side plates.

The rotary disc is positioned in the inner cavity of the cylinder, is sleeved on the rotating shaft, has the axis coincident with the axis of the rotating shaft, has the axial thickness equal to that of the cylinder, has the outer diameter smaller than the inner diameter of the cylinder, is fixedly provided with a hub motor, can rotate around the rotating shaft at a high speed in the clockwise direction under the drive of the hub motor, but cannot move in the axial direction, radially extends out of the axial middle part of the circumferential surface of the rotary disc by a separating ring, and radially extends out of n boosting blocks 8 on the circumferential surfaces of two sides of the separating ring; the outer diameter of the spacer ring is equal to the inner diameter of the cylinder; the n boosting blocks on any side of the turntable are uniformly distributed around the circumferential surface of the corresponding side of the turntable, the inner lateral surfaces of the n boosting blocks are fixedly connected with the outer lateral surfaces of the corresponding sides of the separating rings at corresponding positions, the radial outer end surfaces of the n boosting blocks are movably contacted with the inner circumferential surface of the cylinder, and the axial thickness of the n boosting blocks is equal to the maximum outer diameter of the projectile; the n boosting blocks on any side of the rotary table divide the space between the circumferential surface of the rotary table on the corresponding side and the inner circumferential surface of the cylinder into n arc-shaped shot slots; the radial width of the projectile groove is greater than the maximum outer diameter of the projectile; the shot groove at the lower part of any side of the turntable is just opposite to the rectangular hole on the side plate at the corresponding side.

The cartridge clip box is a transverse horizontal cuboid box, and the inner end or the outer end of the cartridge clip box is opened.

The inner end faces of the two elastic clamping boxes are respectively and vertically fixedly connected with the outer lateral faces of the lower parts of the two side plates, and the inner end openings of the two elastic clamping boxes are respectively communicated with the rectangular holes on the two side plates.

The two cartridge clips are respectively inserted into the two cartridge clip boxes from the outer ports of the two cartridge clip boxes; with the rotation of the turntable around the rotating shaft in the clockwise direction, the shots in the cartridges on any side sequentially enter the n empty shot grooves on the corresponding side of the turntable through the inner ports of the cartridge box on the corresponding side and the rectangular holes on the side plates on the corresponding side, and only one shot can enter each empty shot groove.

The gun seat is fixedly connected with the lower part of the outer circumferential surface of the cylinder and supports the stator on the ground or a carrier, and the stator can rotate left and right or pitch up and down on the gun seat.

The gun handle is parallel to the gun barrel, the front end surface of the gun handle is fixedly connected with the outer circumferential surface of the rear part of the cylinder at a corresponding position along the radial direction, and the gun handle can be operated to realize the left-right rotation or the up-down pitching of the stator.

The turntable is driven by an upper hub motor to rotate around the rotating shaft at a high speed in the clockwise direction, when the projectile enters the projectile groove of the turntable, a corresponding boosting block on the turntable pushes the projectile to accelerate at a high tangential acceleration, and the linear velocity of the projectile is equal to that of the boosting block in a very short time; when the projectile moves to the entrance of the corresponding slide on the cylinder, the inner circumferential surface of the cylinder can not provide centripetal force to the projectile any more, and the projectile automatically moves in the slide in a centrifugal motion to continue inertial motion, then passes through the exit of the slide into the bore of the corresponding barrel, and then is ejected at high speed.

If the rotating speed of the rotary table is s revolutions per minute, the number of shot launched per minute is 2ns, and the launched shot originally has no shell, so that intensive launching of shell-free bullets is realized, and pollution of gunpowder combustion to the environment and quick heating of a gun barrel caused by the gunpowder combustion are eliminated.

Only one projectile may enter each empty projectile slot because of this:

the linear velocity of the projectile passing through the rectangular hole in the side plate is initially zero in the empty projectile slot, the projectile obstructs other projectiles from entering the projectile slot, and when the corresponding booster block pushes the projectile away from the entry position, the projectile slot also leaves the rectangular hole.

After the structure is adopted, as the n boosting blocks are arranged on the turntable, 2n pill grooves for feeding pills are correspondingly formed between the circumferential surface of the turntable and the inner circumferential surface of the cylinder, and 2n pills can be shot every turn of the turntable, so that conditions are created for densely shooting the pills at high speed. This is one of the core creations of the invention.

With this structure, the kinetic energy of the projectile is transferred from the kinetic energy of the rotating disc instead of the chemical energy of the gunpowder, because the projectile is accelerated by the pushing of the boosting block. The invention skillfully utilizes the physical law of energy transfer, thereby making it possible to launch the caseless bullet. This is the second creation at the core of the present invention.

After the structure is adopted, due to the arrangement of the slide way, the accelerated pills can automatically enter the slide way from the pill groove to continue inertial motion, and finally are ejected from the gun chamber. The invention skillfully utilizes the physical law of the relation between the circular motion and the centripetal force and the physical law of inertia, thereby realizing the conversion of the circular motion of the projectile into linear motion. This is the third creation at the core of the present invention.

After adopting such structure, owing to set up the spacer ring on the carousel, owing to set up two slides on the drum, owing to install two barrels on the drum, owing to the cooperation of three with in coordination for two barrels can both launch the pellet simultaneously, and the combat performance improves greatly. This is the fourth creation at the core of the present invention.

After the structure is adopted, because the shot bullet is shell-free, the pollution to the environment and the harm to fighters caused by gunpowder explosion are eliminated, the heat generation of the gun barrel is delayed, and the potential safety hazard of bullet storage and transportation is eliminated. This is an attendant benefit.

After the structure is adopted, the hot weapon returns to the cold weapon, the return is not reversed, but is a greater technical progress of the weapon, the significance of the technical progress of the cold weapon being developed into the hot weapon before more than one hundred years, and the invention can possibly generate far-reaching influence.

Drawings

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

Fig. 1 is a schematic top view of a method of firing a caseless bullet.

Fig. 2 is a schematic horizontal sectional view of the stator of fig. 1.

Fig. 3 is a schematic right side view of the stator of fig. 1, but with the side plates removed from the stator and the spacer ring not shown for clarity.

Detailed Description

As shown in each of fig. 1 to 3, a method of firing a caseless bullet comprises a stator 1, a turntable 6, a cartridge magazine 11, a cartridge 12, a grip 13 and a gun mount.

As shown in fig. 2 and 3, the stator 1 includes a cylinder 2, a side plate 3, a rotary shaft 4, and a gun tube 5.

As shown in fig. 1 and 2, the side plate 3 is a vertical thick circular plate, the inner side surface of which is smooth, and the lower part of which is provided with a rectangular hole for the transverse passing of the projectile 14.

As shown in fig. 2 and 3, the cylinder 2 has a thick wall, a horizontal axis, an outer diameter equal to the outer diameter of the side plate 3, two end faces fixedly connected with the inner lateral faces of the two side plates 3 at corresponding positions, and an axis coincident with the axes of the two side plates 3, is made of high-strength wear-resistant material, has a smooth inner circumferential surface, is provided with two horizontal circular holes 2a along the tangential direction on the upper wall, and is provided with two inclined smooth slideways 9 for the shots 14 to pass through; the two circular holes 2a are divided on both sides of the cylinder 2 and are parallel to each other; the two slide ways 9 are arranged on two sides of the cylinder 2 and are symmetrical with each other; the slide 9 on any side of the cylinder 2 has an inlet 9a on the inner circumferential surface of the corresponding side of the cylinder 2 and an outlet 9b connected to the rear end of the circular hole 2a on the corresponding side.

As shown in fig. 3, the barrel 5 has an outer diameter greater than the inner diameter of the circular hole 2a of the cylinder 2 and a bore 5a through which the projectile 14 passes.

As shown in fig. 3, the rear ends of the two barrels 5 are forcibly inserted into the two round holes 2a of the cylinder 2 in a tight fit manner, the front ends of the two barrels 5 horizontally extend forward, and the rear ports of the upper chambers 5a of the two barrels 5 are smoothly communicated with the outlets 9b of the two slide ways 9.

As shown in fig. 2, both ends of the rotating shaft 4 pass through the shaft holes of the two side plates 3 respectively and are fixedly connected with the two side plates 3 respectively, and the axis of the rotating shaft coincides with the axis of the two side plates 3.

As shown in fig. 2 and 3, the rotating disc 6, which is located in the inner cavity of the cylinder 2, is fitted around the rotating shaft 4, has an axis coinciding with the axis of the rotating shaft 4, has an axial thickness equal to the axial thickness of the cylinder 2, has an outer diameter smaller than the inner diameter of the cylinder 2, is fixedly mounted with a hub motor, is driven by the hub motor to freely rotate around the rotating shaft 4 at a high speed in a clockwise direction, but cannot move in the axial direction, has a separating ring 7 radially extended from the axial middle of the circumferential surface, and has n thrust-assist blocks 8 radially extended from the circumferential surfaces of the separating ring 7 on both sides. The outside diameter of the separating ring 7 is equal to the inside diameter of the cylinder 2. The n boosting blocks 8 on any side of the rotary disc 6 are uniformly distributed around the circumferential surface of the corresponding side of the rotary disc 6, the inner lateral surfaces of the n boosting blocks are fixedly connected with the outer lateral surfaces of the corresponding side of the separating ring 7 at corresponding positions, the radial outer end surfaces of the n boosting blocks are movably contacted with the inner circumferential surface of the cylinder 2, and the axial thickness of the n boosting blocks is equal to the maximum outer diameter of the shot 14. The n booster blocks 8 on either side of the turntable 6 divide the space between the circumferential surface of the turntable 6 on the corresponding side and the inner circumferential surface of the cylinder 2 into n circular arc-shaped shot slots 10. The radial width of the projectile slot 10 is greater than the maximum outer diameter of the projectile 14. The lower shot slots 10 on either side of the rotary disk 6 are directly opposite the rectangular holes in the side plates 3 on the corresponding side.

As shown in fig. 1, the cartridge case 11 is a horizontal rectangular parallelepiped case, and has an open inner end or outer end.

As shown in fig. 1, the inner end surfaces of the two cartridge cases 11 are vertically and fixedly connected to the outer lateral surfaces of the lower portions of the two side plates 3, respectively, and the inner end openings thereof are communicated with the rectangular holes of the two side plates 3, respectively.

As shown in fig. 1, two cartridges 12 are inserted into the two cartridge cases 11 from the outer ports of the two cartridge cases 11, respectively; with the rotation of the rotating disc 6 around the rotating shaft 4 in the clockwise direction, the shots 14 in the cartridges 12 on any side sequentially enter the n empty shot slots 10 on the corresponding side of the rotating disc 6 through the inner ports of the cartridge boxes 11 on the corresponding side and the rectangular holes on the side plates 3 on the corresponding side, and only one shot 14 can enter each empty shot slot 10.

The gun rest, which is fixedly connected to the lower portion of the outer circumferential surface of the cylinder 2, supports the stator 1 on the ground or a carrier, on which the stator 1 can rotate left and right or pitch up and down.

As shown in fig. 1, the grip 13, which is parallel to the barrel 5, has a front end surface fixedly connected to an outer circumferential surface of the rear portion of the cylinder 2 at a corresponding position in a radial direction, and is operated to rotate the stator 1 left and right or pitch up and down.

As shown in fig. 3, the rotating disc 6 is driven by the upper hub motor to rotate around the rotating shaft 4 at a high speed in a clockwise direction, and after the projectile 14 enters the projectile groove 10 of the rotating disc 6, the corresponding boosting block 8 on the rotating disc 6 pushes the projectile 14 to accelerate at a high tangential acceleration, so that the linear velocity of the projectile 14 is equal to that of the boosting block 8 in a very short time. When the shot 14 moves to the entrance 9a of the corresponding slide 9 on the drum 2, the inner circumferential surface of the drum 2 cannot provide a centripetal force to the shot 14 any more, and the shot 14 automatically moves centrifugally into the slide 9 to continue inertial movement, then passes through the exit 9b of the slide 9 into the bore 5a of the corresponding barrel 5, and is then ejected at high speed.

As shown in fig. 3, if the rotation speed of the rotary table 6 is s revolutions per minute, the number of the shot 14 shot per minute is 2ns, and the shot 14 is originally shot without a shell, so that the intensive shooting of the shell-less bullet is realized, and the pollution of gunpowder combustion to the environment and the quick barrel heating caused by the gunpowder combustion are eliminated.

Only one projectile 14 may enter each empty projectile trough 10 because of this:

as shown in fig. 3, the linear velocity of the projectile 14 passing through the rectangular aperture in the side plate first to the empty projectile slot 10 is zero, and the projectile 14 blocks other projectiles 14 from re-entering the projectile slot 10, and when the corresponding booster block 8 pushes the projectile 14 out of the entry position, the projectile slot 10 also leaves the rectangular aperture.

The embodiments of the present invention are described in detail above with reference to the accompanying drawings. The present invention is not limited to the above-described embodiments, and various changes can be made without departing from the spirit of the present invention within the knowledge of those skilled in the art. Variations that do not depart from the gist of the invention are intended to be within the scope of the invention.

Claims (2)

1. A method of firing a caseless bullet, comprising:

the method for launching the shell-less bullet comprises a stator (1), a turntable (6), a cartridge clip box (11), a cartridge clip (12), a gun handle (13) and a gun seat;

the stator (1) comprises a cylinder (2), a side plate (3), a rotating shaft (4) and a gun barrel (5);

the side plate (3) is a vertical thick circular plate, the inner side surface of the side plate is smooth, and the lower part of the side plate is provided with a rectangular hole through which the projectile (14) can transversely pass;

the cylinder (2) is thick in cylinder wall, horizontal in axis, equal to the outer diameter of the side plates (3), fixedly connected with the inner lateral surfaces of the two side plates (3) at corresponding positions at two end surfaces respectively, superposed with the axes of the two side plates (3), made of high-strength wear-resistant materials, smooth in inner circumferential surface, provided with two horizontal round holes (2a) along the tangential direction on the upper cylinder wall, and provided with two inclined smooth slideways (9) for the shots (14) to pass through; the two round holes (2a) are divided at two sides of the cylinder (2) and are parallel to each other; the two slide ways (9) are arranged at two sides of the cylinder (2) and are symmetrical with each other; a slide way (9) on any side of the cylinder (2), wherein an inlet (9a) of the slide way is positioned on the inner circumferential surface of the corresponding side of the cylinder (2), and an outlet (9b) of the slide way is connected with the rear end of the round hole (2a) of the corresponding side; .

The outer diameter of the barrel (5) is larger than the inner diameter of a round hole (2a) on the cylinder (2), and a bore (5a) of the barrel can allow the shot (14) to pass through;

the rear ends of the two gun tubes (5) are forcibly inserted into the two round holes (2a) on the cylinder (2) in a tight fit mode respectively, the front ends of the two gun tubes (5) horizontally extend forwards, and the rear ports of the upper gun chambers (5a) of the two gun tubes (5) are smoothly communicated with the outlets (9b) of the two slide ways (9) respectively;

the two ends of the rotating shaft (4) respectively pass through the shaft holes on the two side plates (3) and are respectively fixedly connected with the two side plates (3), and the axes of the rotating shaft and the axes of the two side plates (3) are overlapped;

the rotating disc (6) is positioned in the inner cavity of the cylinder (2), is sleeved on the rotating shaft (4), has an axis which is superposed with the axis of the rotating shaft (4), has an axial thickness which is equal to the axial thickness of the cylinder (2), has an outer diameter which is smaller than the inner diameter of the cylinder (2), is fixedly provided with a hub motor, can freely rotate around the rotating shaft (4) at a high speed in a clockwise direction under the drive of the hub motor, but cannot move in the axial direction, radially extends out of the axial middle part of the circumferential surface of the rotating disc (6) to form a separating ring (7), and radially extends out of n boosting blocks (8) on the circumferential surface of each of two sides of the separating ring (7); the external diameter of the separating ring (7) is equal to the internal diameter of the cylinder (2); n boosting blocks (8) on any side of the rotary disc (6) are uniformly distributed around the circumferential surface of the corresponding side of the rotary disc (6), the inner lateral surfaces of the n boosting blocks are fixedly connected with the outer lateral surfaces of the corresponding sides of the separating rings (7) at corresponding positions, the radial outer end surfaces of the n boosting blocks are movably contacted with the inner circumferential surface of the cylinder (2), and the axial thickness of the n boosting blocks is equal to the maximum outer diameter of the shot (14); n boosting blocks (8) on any side of the rotary disc (6) divide the space between the circumferential surface of the rotary disc (6) on the corresponding side and the inner circumferential surface of the cylinder (2) into n arc-shaped pill grooves (10); the radial width of the shot groove (10) is larger than the maximum outer diameter of the shot (14); the shot groove (10) positioned below any side of the turntable (6) is just opposite to the rectangular hole on the side plate (3) on the corresponding side;

the cartridge clip box (11) is a transverse horizontal cuboid-shaped box, and the inner end or the outer end of the cartridge clip box is open;

the inner end surfaces of the two elastic clamping boxes (11) are respectively and fixedly connected with the outer lateral surfaces of the lower parts of the two side plates (3) vertically, and the inner end openings of the two elastic clamping boxes are respectively communicated with the rectangular holes on the two side plates (3);

the two cartridge clips (12) are respectively inserted into the two cartridge clip boxes (11) from the outer ports of the two cartridge clip boxes (11); with the rotation of the turntable (6) around the rotating shaft (4) along the clockwise direction, the shots (14) in the shot clips (12) on any side sequentially enter n empty shot slots (10) on the corresponding side of the turntable (6) through the inner ports of the shot clip boxes (11) on the corresponding side and the rectangular holes on the side plates (3) on the corresponding side, and only one shot (14) can enter each empty shot slot (10);

the gun seat is fixedly connected to the lower part of the outer circumferential surface of the cylinder (2) and supports the stator (1) on the ground or a carrier, and the stator (1) can rotate left and right or pitch up and down on the gun seat;

the gun handle (13) is parallel to the gun barrel (5), the front end surface of the gun handle is fixedly connected with the outer circumferential surface of the rear part of the cylinder (2) at a corresponding position along the radial direction, and the gun handle can be operated to realize the left-right rotation or the up-down pitching of the stator (1);

the rotary disc (6) is driven by an upper hub motor to rotate around the rotating shaft (4) at a high speed in a clockwise direction, when the shot (14) enters a shot groove (10) of the rotary disc (6), a corresponding boosting block (8) on the rotary disc (6) pushes the shot (14) to accelerate at a high tangential acceleration, and the linear velocity of the shot (14) is equal to that of the boosting block (8) in a very short time; when the projectile (14) moves to the inlet (9a) of the corresponding slide (9) on the cylinder (2), the inner circumferential surface of the cylinder (2) can no longer provide centripetal force to the projectile (14), the projectile (14) automatically enters the slide (9) in centrifugal motion and continues inertial motion, then enters the bore (5a) of the corresponding barrel (5) through the outlet (9b) of the slide (9), and then is ejected at high speed;

if the rotating speed of the rotary table (6) is s revolutions per minute, the number of the shot (14) shot per minute is 2ns, and the shot (14) is originally without a shell, so that the intensive shooting of the shell-free bullets is realized, and the pollution of gunpowder combustion to the environment and the quick heating of the gun barrel caused by the combustion of the gunpowder are eliminated.

2. The method of shooting a caseless bullet as in claim 1 wherein:

only one projectile (14) is possible in each empty projectile trough (10) because of this:

the linear velocity of the projectile (14) which firstly enters the empty projectile groove (10) through the rectangular hole in the side plate is zero, the projectile (14) prevents other projectiles (14) from entering the projectile groove (10), and when the corresponding boosting block (8) pushes the projectile (14) to leave the entering position, the projectile groove (10) also leaves the rectangular hole.

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