RU2538475C1 - Method of missile acceleration in barrel bore with spinning and missile to this end - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: during acceleration of missile in barrel bore, powder gas overpressure is developed between barrel bottom and missile to create gas flow directed to missile rear pushing said missile toward outlet. Note here that zone adjoining the missile outer surface is provided with missile gas ply pressure increased area is formed to impart extra acceleration and spinning in barrel bore owing to radial component of gas ply pressure application vector. Groove is made on missile to shape an appropriate ledge. Said helical groove extends from missile body tail to head for to make a gas ply passage. Ledges have holes (cut-outs) to make gas ply passages.

EFFECT: higher accuracy of fire and acceleration, better stabilization and centring.

13 cl, 3 dwg

Description

The present invention relates to small arms and can be used when firing mainly from smooth-bore weapons in order to increase accuracy and speed of a missile body (bullet, projectile) and thus increase the firing range and lethal force of the projectile.

A known method of dispersal of a missile projectile in the barrel [RU 2486426 C2, F41A 2/18, 06/27/2013], in accordance with which they increase the initial velocity of the bullet, the accuracy of the battle, reduce the sound level of the shot, heat the barrel and return the weapon by moving during the shot to the shell space of the air in the barrel channel in front of the bullet, which is passed between the surface of the leading part of the bullet and the surface of the barrel channel through various forms of recesses (slots, grooves) in it, for example, longitudinal and / or oblique-longitudinal grooves made on fields between rifling, and / or inclined longitudinal grooves cut into parts or all rifling by increasing the cross-sectional area of the rifling, and in the section of the bore with the pressure of the powder gases in the projectile space exceeding the pressure of the compressed air at the bullet’s shoulder, the movement of compressed air discontinuous recesses are carried into the projectile space, into which, using the overlap-opening of the air passage into the recess, the leading part of the bullet during its movement in the barrel channel, inject air through of the bullet tip when moving the bullet’s shoulder along the recess, stop pumping after the recess is completely blocked by the leading part of the bullet and, after opening the recess with further movement of the bullet, transfer air into the projectile space, and in the section of the barrel channel with the pressure of powder gases it is less than the pressure of compressed air at the shoulder bullets, the movement of compressed air into the projectile space is carried out through discontinuous recesses and / or through continuous oblique longitudinal recesses, the discontinuous recesses being located after the hole of the barrel channel, on which the process of cutting the bullet into the rifling during the shot is completed, and until the point when the tip stops the injection of compressed air into the recesses at the end of the barrel, and the continuous oblique longitudinal recesses are located after the section starting from which the pressure of the powder gases at the supersonic speed of the bullet may become less than the air pressure at the shoulder of the bullet, and to the same place at the muzzle end as the intermittent recesses, the initial speed is increased, reducing the drag force of the air by moving it in after the completion of the process of cutting the bullet into the rifling, reducing the friction force between the bullet and the bore due to the reduction of the friction surface in the places of recesses, and, when the pressure of the powder gases is less than the pressure of compressed air at the shoulder of the bullet, slowing down the pressure drop of the powder gases in the projectile due to the arrival of compressed air from the bore in the barrel, the sound level of the shot is reduced, and the accuracy of the battle is increased, preventing the formation of a "ballistic wave pop" when the bullet hits, the temperature of the powder gas and heating of the barrel is reduced by moving less heated air than gunpowder gases into the projectile space after the process of cutting the bullet into the rifling, while the drag of the air, as well as the temperature of the powder gases and the heating of the barrel are reduced after the process of cutting the bullet into the rifling, or start to carry out earlier, letting air into the projectile space during the cutting of a bullet into rifling, in intermittent recesses increase the air pressure to a pressure exceeding the pressure of gunpowder gases, and after opening the recess, air is released into the projectile space, slowing down the pressure drop of the powder gases and further increasing the initial velocity of the bullet, or, to reduce the recoil of the weapon and further reduce the heating of the barrel, the air is compressed in part or in all intermittent recesses to less than outside the pressure space, which ensures the entrance to the extraction of powder gases, their expansion with decreasing temperature, as well as a dynamic impact on the wall of the extraction used as a muzzle brake, they receive different air pressure in the recesses blocked by the bullet by performing a threaded barrel with recesses of different volumes, and in the grooves made by the rifling, in addition, the air pressure is additionally increased during the overlapping of the grooves by the leading part of the bullet, the compressed air is moved into the projectile space through discontinuous longitudinal and / or oblique longitudinal and / or transverse grooves located in the fields between the grooves and / or intersecting the grooves and / or adjacent to the grooves and / or through the gap the grooves along the grooves, the grooves adjacent to the grooves or intersecting the grooves should not impair the function of the grooves, and the intermittent longitudinal grooves made in the fields between the grooves or intersecting the grooves are placed in the direction of the grooves and / or against, preventing or reducing action on the weapon of the torque that occurs when the bullet rotates along the rifling, and also formed by the reaction of a stream of air or powder gases when they enter the groove, provide a seal of the powder gases on the entire length of the bore, positioning continuous and intermittent recesses to the point where the tip stops pumping compressed air into the recesses at the end of the barrel, or, to further reduce the sound level of the shot, part of the powder gases is released from the bore before the bullet leaves it, passing them through intermittent or continuous grooves made immediately before the muzzle end, and the length of these intermittent grooves does not depend on the length of the leading part of the bullet.

The disadvantage of this method is its relatively high complexity, due to the need to perform a relatively large number of auxiliary operations, and a relatively narrow scope, due to the fact that the rotation of the bullet is carried out through the use of a rifled barrel, i.e. the use of friction forces, which reduces the acceleration rate of a missile projectile, reduces the firing range and the lethal force of the projectile.

In order to increase the speed of dispersal of the projectile, increase the firing range and the lethal force of the projectile, you can use smoothbore weapons and the corresponding methods of dispersal of the projectile. In particular, a method is also known [US 3001609, 184/18, 09/26/1961], according to which an excess pressure of powder gases is created between the bottom of the barrel and the projectile of cylindrical shape to cause the directional movement of the projectile in the barrel under the action of the carrier gas layer and is formed gas suspension, where to increase the speed of the projectile by reducing friction, part of the projectile is made in the form of a gas-static suspension, the power of which is provided by the powder produced by the shot mi gases.

The disadvantage of this technical solution is the relatively low efficiency due to the emergence of non-stationary motion modes leading to skew of the projectile in the barrel, as well as increased sensitivity that implements the method of construction to external vibrations. In addition, this method has a relatively narrow scope, because when it is implemented, the missile projectile does not gain rotation, which reduces the accuracy (accuracy) of firing.

In addition, there is a method of increasing the speed of a missile projectile during firing [RU 2448320 C2, F41A 1/00, 04/20/2012], based on the reduction of friction forces during its movement in the barrel, according to which, when fired, a pulse of high-power acoustic vibrations is fed into the barrel the direction of the vector of the maximum component of the velocity of the missile projectile, duration T, determined from the ratio T> L / V + dT, where L is the barrel length; V is the averaged muzzle velocity of a propelled body; dT is the lead time of the impulse, the action of which ceases after the body takes off from the barrel.

The disadvantage of this technical solution is its relatively high complexity, caused by the necessity of delivering a high-power acoustic oscillation pulse to the barrel in the direction of the vector of the maximum component of the velocity of the missile projectile, and relatively low efficiency due to the emergence of non-stationary motion modes leading to skew of the missile projectile in the barrel , as well as increased sensitivity that implements the design method to external vibrations. In addition, this method also has a relatively narrow scope, because when it is implemented, a missile projectile does not gain rotation, which reduces the accuracy (accuracy) of fire.

The closest in technical essence to the proposed method is a technical solution [RU 2285226 C2, F42B 14/04, 04/25/2005], according to which previously between the bottom of the barrel and the projectile projectile create an excess pressure of the powder gases and form a carrier gas layer for providing directed movement of the projectile to the barrel outlet, and form a gas suspension to create additional pressure in the carrier gas layer by supplying gas under pressure in the supply cavity in t le projectile, through the feeding device in the area between the outer cylindrical surface of the projectile and the inner walls of the barrel, and the supply of gas under pressure in the supply cavity in the body of the projectile is carried out by burning a substance having a high burning rate, using a termite wick in the back missile projectile connected to the supply cavity through the hole.

The disadvantage of the closest technical solution is its complexity, due to the need to create a gas suspension and create additional conditions for burning a substance with a high burning rate, as well as a relatively narrow scope, because when it is implemented, a missile shell does not gain rotation, which reduces accuracy (accuracy ) shooting.

The problem solved by the proposed invention is to simplify the method while expanding the scope of use by allowing the projectile to rotate when it is dispersed in smoothbore weapons to increase accuracy (accuracy) of fire.

The required technical result is to simplify the method while expanding the scope of use by providing the possibility of rotation of a missile projectile during acceleration in smoothbore weapons to increase accuracy (accuracy) of firing.

The problem with the method is solved, and the required technical result with respect to the method is achieved by the fact that in the method, in which the excess pressure of the powder gases is created between the bottom of the barrel and the projectile with a cylindrical body and a carrier gas flow is generated in the direction of the rear of the projectile to ensure its directional movement to the outlet of the barrel, according to the invention relative to the method, in the area adjacent to the outer surface of the core cylinders of a cylindrical form of a projectile, form a zone with an increased pressure area of the carrier gas layer on the projectile to give it additional acceleration in the direction of the barrel outlet and rotational movement in the barrel channel by forming a vector of application of the pressure force of the carrier gas layer with a radial component.

Also known are shells that are used to throw small arms and guns from barrels.

In particular, a bullet for a hunting cartridge is known [RU 2056620 C1, F42B 30/02, 20.03.1996], containing a metal shell and a lead core, made with a free volume in the head part at the top, and the free volume is made for a length of 0.7 length an annular groove is made at a distance of 0.2-0.5 of the length of the warhead from the top on the surface of one of the sides of the shell (external or internal), while the bottom of the groove is mated to the surface of the shell and has a constant or increasing distance from the axis of the bullet when away from the peaks s, and the minimum shell thickness in the groove zone is 0.1-0.5 of the average shell thickness on the leading part.

The disadvantage of these bullets is the relatively low speed of departure from the barrel and the associated relatively small firing range and relatively low lethal force.

Also known is a bullet [RU 37822 U1, F42B 12/34, 05/10/2004], containing several radial segments made of solid heavy material, as well as the nose, consisting of these radial segments and having an annular groove in the rear section for connection with the tail part made of lighter material with the ability to fix the end sections of the radial segments.

The disadvantage of this technical solution is the relatively low reliability caused by the unreliable fastening of the segments of the bullet body with a polyethylene insert located in the annular groove in the front, because the insert itself is located in the groove without interference and during its acceleration in the barrel of the weapon comes out of it and when the bullet leaves the barrel, the segments simply fall apart and fly in an arbitrary direction.

In addition, a rifled projectile bullet is known [RU 121052 U1, F42B 12/04, 10.10.2012] having a head part, a leading part and a tail part made in the form of a truncated cone, tapering to the rear end, while on the side surface of the tail the parts are made of the same screw-shaped slices of variable depth between the cutting edge and the bottom of the cutting, and the cutting is evenly distributed along the lateral surface of the tail part relative to the horizontal axis of the bullet, and the line of the cutting edge forms an angle α≤45 ° with the horizontal axis of the bullet, and the edges are threaded can be made in a rectilinear or curvilinear shape, the length of the tail can be 0.2–0.5 of the bullet length, the maximum cutting depth can be 0.05–0.2 of the radius of the rear end of the bullet, the number of cuts can be at least three, the cut edge , which determines the depth of the cut, forms an angle β = 90 ° with a tangent to the bottom of the cut, and the start of the cut rib is made on one line parallel to the horizontal axis of the bullet, with the end of the next cut rib.

The disadvantage of this technical solution is the relatively low speed of departure from the barrel and the associated relatively small firing range and relatively low lethal force.

The closest in technical essence to the proposed one is a bullet (projectile for throwing from the barrel) [RU 77413 U1, F42B 30/02, F42B 12/34, 10/20/2008] containing a metal body of cylindrical shape, the nose of which is conical and integral with housing, an annular groove on the side surface of the housing at the junction of the cylinder of the housing into the cone by the nose and an insert installed in this groove, while on the cylindrical part of the housing there are several annular grooves located along its length, the groove width being made once personal in its depth and increasing towards the center from the outer surface of the housing, and the inserts in the bores are mounted with a protrusion above the side surface of the housing, and in the particular case, the grooves in the section are made either in the form of a truncated cone, or T-shaped, and the protrusion of the inserts above the side surface of the housing is made in the range of 0.1-0.5 mm.

The disadvantage of the closest technical solution is the relatively low speed of departure from the barrel and the associated relatively small firing range and relatively low lethal force, as well as relatively narrow functionality due to the fact that the bullet (projectile) does not receive rotation around the longitudinal axis, which reduces accuracy (accuracy) of fire.

The problem to which the proposal regarding the design of the projectile is directed is to increase the speed of its acceleration and expand the functionality by ensuring stabilization and self-centering of the projectile in order to increase the range and accuracy (accuracy) of fire and the lethal force of the projectile.

The required technical result is to increase the speed of its acceleration and expand the functionality by ensuring stabilization and self-centering of the projectile in order to increase the range and accuracy (accuracy) of fire and lethal force of the projectile.

The problem with the device is solved, and the required technical result is achieved in that in a missile projectile containing a metal body of cylindrical shape, the bow of which is made integral with it and along its longitudinal axis, while on the surface of the metal body of a cylindrical shape in the direction perpendicular to it the longitudinal axis, at least one groove is made with the formation of a protrusion corresponding to it, according to the invention with respect to the device, at least one groove made helical from the tail of the cylindrical metal body to its nose for passage between the projectile and the barrel of the carrier gas layer formed between the bottom of the barrel and the tail of the projectile when it is thrown, and in the protrusions there are holes or cutouts for the passage of the carrier gas layer between sections of at least one helical groove in the direction from the tail to the bow of the projectile.

In addition, the required technical result is achieved by the fact that the length of at least one groove corresponds to an integer number of its revolutions around the longitudinal axis of the metal body of a cylindrical shape.

In addition, the desired technical result is achieved by the fact that the depth of at least one helical groove is made constant.

In addition, the required technical result is achieved by the fact that the depth of at least one helical groove is made increasing from the tail to the bow of the projectile.

In addition, the desired technical result is achieved in that the step of at least one screw-shaped groove is made increasing from the tail to the nose of the projectile.

In addition, the desired technical result is achieved by the fact that the number of helical grooves is equal to either two or three.

In addition, the desired technical result is achieved by the fact that the holes or cutouts in the protrusions are made the same.

In addition, the desired technical result is achieved by the fact that the holes or cutouts in the protrusions in the direction from the rear to the side of the nose of the projectile are made increasing in size.

In addition, the desired technical result is achieved by the fact that the holes in the protrusions are made either round or square.

In addition, the required technical result is achieved by the fact that the cutouts in the protrusions are rectangular in plan.

In addition, the desired technical result is achieved in that the holes or cutouts made in the protrusions are placed at equal distances from the longitudinal axis of the projectile.

In addition, the desired technical result is achieved by the fact that the holes or cuts are placed along the protrusions evenly without the possibility of coincidence at distances of one revolution of the screw-shaped groove.

The drawing shows:

figure 1 - missile projectile (bullet);

figure 2 - experimental results (the results of exposure to an aluminum plate with a standard lead bullet weighing 0.51 grams);

figure 3 - the results of the experiment (the results of exposure to the aluminum plate of a lead bullet of the proposed design weighing 0.51 grams).

The missile projectile (bullet) contains a metal body 1 of a cylindrical shape, the bow 2 of which is made integral with it and along its longitudinal axis.

At least one screw-shaped groove 3 is formed on the surface of the cylindrical metal housing 1 in the direction perpendicular to its longitudinal axis with the formation of a protrusion 4 corresponding to it from the tail of the cylindrical metal housing to its nose 2 for passage between the projectile and the barrel a carrier gas layer formed between the bottom of the barrel and the tail of the projectile when it is thrown.

An advantageous embodiment of the projectile is when the length of at least one screw-shaped groove 3 corresponds to an integer number of revolutions around the longitudinal axis of the cylindrical metal casing, and the depth of at least one screw-shaped groove 3 is made constant.

To ensure a more stable position of the projectile in the barrel, the depth of at least one screw-shaped groove 3 can be made increasing from the tail to the bow 2 of the projectile, and the step of at least one screw-shaped groove 3 can also be made increasing from the tail to the bow of the 2 missile projectile.

In the protrusions 4, either openings 5 or cutouts can be made for passage of the carrier gas layer between the sections of at least one screw-shaped groove 3 in the direction from the tail to the nose 2 of the projectile.

The number of helical grooves 3, it is advisable to perform equal to two or three, and the holes 5 or cutouts in the protrusions 4 are the same. The holes 5 or cutouts in the protrusions 4 in the direction from the tail to the side of the bow of the projectile can be made increasing in size in order to stabilize the position of the projectile in the barrel. The holes 5 themselves in the protrusions 4 can be made either round or square, and the cut-outs are rectangular in plan.

To ensure a projectile projectile that is stable in the direction of movement of the projectile in the barrel, holes 5 or cutouts made in the projections 4 are placed at equal distances from the longitudinal axis of the projectile and are evenly distributed along the projections 4 without the possibility of coincidence at distances of one revolution of the helical groove. The latter eliminates the possibility of a straight flow of the carrier gas layer along the shell of the projectile, which reduces the effect of its rotation in the barrel and reduces the effect of accelerating movement along the barrel.

The proposed method is implemented using the proposed design of a missile projectile (bullet) as follows.

A missile projectile (bullet) is inserted into the barrel. The bullet may be an element of the cartridge, and when excessive pressure of the powder gases is created between the bottom of the barrel and the bullet by igniting the powder charge (not shown in the drawing), a carrier gas layer is formed in the direction of the tail of the projectile (bullet) to ensure its directional movement to the barrel outlet (not shown in the drawing).

As a result, the carrier gas layer first presses on the rear surface of the rear part of the body 1 of the projectile and, at the same time, part of the carrier gas flows into the spiral grooves 3. Due to the kinetic (sailing) energy transfer of the carrier gas stream to the walls of the spiral grooves 3, the projectile is accelerated along the axis trunk and additionally formed radial acceleration, since the walls of the spiral grooves 3 are made at an angle to the vector of motion of the carrier gas stream.

Holes 5 or cutouts allow for the penetration of a larger volume of the carrier gas stream and enhances the effect of longitudinal and radial acceleration due to the transfer of kinetic energy from a larger volume of the carrier gas stream.

The positive effect of the use of the invention, which is associated with an increase in the acceleration speed of a missile projectile and giving it rotational motion in the barrel channel, is manifested as follows.

In a missile projectile without helical grooves 3 and holes 5 or cutouts, the gas flow force F acting on the rear surface of the tail of the missile projectile is equal to

F _s = S * P,

where S is the area of the rear surface of the tail of the missile;

P - gas pressure in the barrel.

In the proposed method and the device implementing it, one more driving force is added - the aerodynamic drag force of the gas flow passing through the screw-shaped grooves 3. It is calculated by the formula for sailing kinetic energy transfer for surfaces located at an angle to the carrier gas stream:

traction - a force directed along the bore Fx = Cx ½ ρ V ² S, twisting (lifting) force Fy = Cu ½ ρ V ² S,

where Cx, Cy is the coefficient of conversion of the energy of the gas stream into the kinetic energy of the bullet along the X axis (axis directed along the bore) and the Y axis (axis directed perpendicular to the bore), respectively;

p is the specific density of the carrier gas duct;

V is the velocity of the carrier gas duct passing through the annular grooves;

S _t - the total area of the protrusions formed by annular grooves, inhibiting the gas flow.

The total driving force in the direction of the axis of the barrel channel will be equal to the sum of the pressure force on the rear surface of the tail of the projectile and the force of aerodynamic traction

F = F _s + Fx

And the twisting force (lifting aerodynamic force) will be equal to

Fy = Cu ½ ρ V ² S

Figure 2 presents the results of testing the use of a bullet-analog when shooting at a thin aluminum sheet, when the bullet's energy was not enough to penetrate it. Figure 3 - sheet pierced by a bullet with the proposed design, which implements the proposed method. Similarly, when firing at a range, the unconditional effect of increasing the firing range by 15-20% was observed when using a bullet of the proposed design with a similar increase in the accuracy of firing up to 10%.

Thus, thanks to the proposed improvements to the throwing method and the proposed design of the missile projectile that implements the method, the required technical result is achieved by expanding the scope of the method and expanding the functionality of the device by introducing an additional arsenal of technical means providing rotational movement of the projectile around its longitudinal axis with the purpose of increasing the range and accuracy (accuracy) of shooting and the lethal force of a missile projectile.

Claims (13)

1. The method of dispersal of a missile projectile in the bore with rotation, according to which preliminary between the bottom of the barrel and the missile projectile with a cylindrical body create excessive pressure of the powder gases and form a carrier gas flow in the direction of the rear of the missile projectile to ensure its directional movement to the barrel outlet characterized in that in the area adjacent to the outer surface of the body of the cylindrical shape of the projectile, form a zone with an increased pressure area of the bearing ha the layer to the projectile to give it additional acceleration in the direction of the barrel outlet and rotational movement in the barrel channel by forming a vector of application of the pressure force of the carrier gas layer with the radial component. 2. A missile projectile for implementing the method according to claim 1, containing a metal body of cylindrical shape, the nose of which is made integral with it and along its longitudinal axis, while on the surface of the metal body of a cylindrical shape in the direction perpendicular to its longitudinal axis, made at least one groove with the formation of a protrusion corresponding to it, characterized in that at least one groove is made helical from the tail of the cylindrical metal body to its nose ty for passage between the missile projectile and the barrel of the carrier gas layer formed between the bottom of the barrel and the tail of the projectile when it is thrown, and either holes or cuts are made in the protrusions for the carrier gas layer to pass between sections of at least one screw-shaped groove in the direction from the tail to the bow of the projectile. 3. A missile projectile according to claim 2, characterized in that the length of at least one groove corresponds to an integer number of its revolutions around the longitudinal axis of the metal body of a cylindrical shape. 4. A missile projectile according to claim 2, characterized in that the depth of at least one screw-shaped groove is made constant. 5. A missile projectile according to claim 2, characterized in that the depth of at least one helical groove is made increasing from the tail to the nose of the missile projectile. 6. A missile projectile according to claim 2, characterized in that the step of at least one helical groove is made increasing from the tail to the nose of the missile projectile. 7. A missile projectile according to claim 2, characterized in that the number of helical grooves is equal to either two or three. 8. A missile projectile according to claim 2 or 7, characterized in that the holes or cutouts in the protrusions are made the same. 9. A missile projectile according to claim 2 or 7, characterized in that the holes or cutouts in the protrusions in the direction from the tail to the bow of the missile are made increasing in size. 10. A missile projectile according to claim 2 or 7, characterized in that the holes in the protrusions are made either round or square. 11. A missile projectile according to claim 2 or 7, characterized in that the cutouts in the protrusions are rectangular in plan. 12. A missile projectile according to claim 2 or 7, characterized in that the holes or cutouts made in the protrusions are placed at equal distances from the longitudinal axis of the missile projectile. 13. A missile projectile according to claim 2 or 7, characterized in that the holes or cuts are placed along the protrusions evenly without the possibility of coincidence at distances of one revolution of the helical groove.

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