RU2536004C1 - Method of missile acceleration during firing and missile for method implementation - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: during acceleration of a missile while firing, between barrel bottom and a missile with a housing of cylindrical form preliminary generated is excess pressure of powder gases and formed is carrying gas layer in the direction of missile heal to provide its directed motion to output of the barrel hole. In the area adjacent to external surface of missile housing of cylindrical form formed is a zone with enlarged pressure area of carrying gas layer on the missile to impart additional acceleration in direction of output of the barrel hole. The missile contains metal housing of cylindrical form which nose part is designed along longitudinal axis and conjointly with the housing. On the housing surface successively along its length in direction perpendicular to the missile longitudinal axis performed are annular grooves forming corresponding annular projections. Each of annular projection is provided with holes. Holes are arranged at equal distances from each other and from longitudinal axis, and holes in neighbouring annular projections are performed nonoverlapping.

EFFECT: improving missile acceleration speed for increase of firing distance and missile wounding power.

12 cl, 4 dwg

Description

The present invention relates to the field of military equipment and can be used when firing smooth-bore and rifled weapons with the aim of increasing the speed of the missile body (bullet, projectile) and thus increasing the lethal force and the firing range of small arms or artillery weapons.

One of the possible ways to increase the firing range and lethal force of the weapon is to reduce losses during the passage of the projectile along the barrel, the main source of which is the friction of the projectile on the inner surface of the barrel, and, if possible, giving the missile body additional acceleration. Known ways to achieve this effect.

Known, in particular, the method of dispersal of a missile projectile in the barrel [Bolshtyansky A.P. On the possibility of using non-contact centering of a projectile in a smoothbore gun. An article in the collection of materials of the Interregional Scientific and Technical Conference "Multipurpose tracked and wheeled vehicles: development, production, combat effectiveness, science and education. Omsk, 2002. Part 1. - p. 43-45], according to which an excess pressure of powder gases is created between the bottom of the barrel and the projectile of a cylindrical shape to cause the directional movement of the projectile in the barrel under the action of the carrier gas layer and a gas suspension is formed to create additional pressure in the carrier gas layer by supplying gas under pressure in the supply cavity in the body of the projectile through the supply device to the area between the outer cylindrical surface of the missile arade and the inner walls of the trunk.

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 design method to external vibrations.

There is also known a method [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 a cylindrical shape to cause the directional movement of the projectile in the barrel under the action of the carrier gas layer and a gas suspension is formed, where, in order to increase the speed of a missile projectile due to the reduction of friction forces, part of the projectile is made in the form of a gas-static suspension, the power of which is provided by powder gases formed as a result of the shot.

The disadvantage of this technical solution is also 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, which implements the design method to external vibrations.

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 a decrease in the friction forces when it moves in the barrel, according to which a high-power acoustic pulse is supplied to the barrel during firing in 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.

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 preliminary between the bottom of the barrel and the projectile projectile create an excess pressure of the powder gases and form a carrier gas layer to ensure 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 barely projectile, through the feeding device into the region between the outer cylindrical surface of the missile 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 substances with a high burning rate.

The problem solved by the proposed invention is to simplify the method while increasing the acceleration speed to increase the firing range and increase the lethal force of the projectile.

The required technical result is to simplify the method while increasing the acceleration speed of the projectile to increase the firing range and increase the lethal force of the projectile.

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 according to 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 layer is formed in the direction of the rear of the projectile to ensure its directional movement to the outlet of the barrel according to the invention with respect to the method in the area adjacent to the outer lateral surface ti housing cylindrical shape propelled projectile, form a zone of increased pressure bearing area of the gas layer on the metal shell to impart additional acceleration in the direction of the barrel outlet.

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, 03/20/1996], 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 the length of the head part, at a distance of 0.2-0.5 the length of the head part from the top, an annular groove is made 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 moving away from the top They are, 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 tail part made of lighter material with the possibility of fixing 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 can come out of it, therefore, when the bullet leaves the barrel, segments can fly out in arbitrary directions.

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, 20.10.2008], containing a metal body of a cylindrical shape, the bow of which is conical and integral with the 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 width of the grooves being made 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-shape, 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 of the projectile.

The problem to which the proposal regarding the design of the missile projectile is directed is to increase the acceleration speed in order to increase the firing range and the lethal force of the missile projectile.

The required technical result is to increase the acceleration speed in order to increase the firing range and the lethal force of the projectile.

The problem with the device is solved, and the required technical result is achieved by the fact that in a device containing a metal body of cylindrical shape, the nose of which is made along the longitudinal axis of the metal body of a cylindrical shape and at the same time with a metal body of a cylindrical shape, while on the surface of a metal body of a cylindrical shape sequentially along its length in the direction perpendicular to the longitudinal axis of the projectile, at least one ring I groove with the formation of its corresponding ring-shaped protrusions, according to the invention, with respect to the projectile being projected, at least two holes or two cuts are made in each of the ring-shaped protrusions, and the holes or cuts made in the respective ring-shaped protrusions are placed at equal distances from each other and from the longitudinal axis of the device, and the holes or cutouts in adjacent annular protrusions are made non-overlapping.

In addition, the required technical result is achieved by the fact that the depth of the annular grooves is made the same.

In addition, the desired technical result is achieved in that the number of holes or cuts made in the respective annular protrusions is equal to either two, or three, or four.

In addition, the required technical result is achieved by the fact that the depth of the annular grooves is made increasing from the back to the side of the bow of the projectile.

In addition, the required technical result is achieved by the fact that the annular grooves are made perpendicular to the longitudinal axis of the projectile.

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

In addition, the desired technical result is achieved in that the holes or cutouts in the annular protrusions in the direction from the tail to the side of the bow of the projectile are made increasing in size.

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

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

In addition, the required technical result is achieved in that the radius of the base of the nose, which is made conical, does not exceed the radius of the body of the cylindrical shape minus the distance from the longitudinal axis of the device to the nearest edge of the hole or cut in the ring groove closest to the nose.

In addition, the required technical result is achieved in that the radius of the base of the bow, which is made conical, is equal to the radius of the nearest annular groove.

The drawing shows:

figure 1 - missile projectile (bullet) is a side view;

figure 2 - missile projectile (bullet) - front view;

figure 3 - the results of the experiment (the results of exposure to an aluminum plate with a standard lead bullet weighing 0.51 grams);

figure 4 - the results of the experiment (the results of exposure to an aluminum plate of a lead bullet of the proposed design weighing 0.51 grams).

The missile projectile (bullet) contains a metal body 1 of cylindrical shape, the nose 2 of which is made along the longitudinal axis of the metal body 1 of a cylindrical shape and at the same time with it.

In addition, on the surface of the metal housing 1 of a cylindrical shape in series along its length in a direction perpendicular to the longitudinal axis of the metal housing 1 of a cylindrical shape, at least at least one annular groove 3 is formed with the formation of corresponding annular protrusions 4.

In each of the annular projections 4, at least two openings 5 or cutouts are made, the openings being predominantly round and the openings rectangular in plan.

Holes 5 or cutouts made in the respective annular protrusions 4 are placed uniformly and symmetrically throughout the annular protrusion at equal distances from each other and from the longitudinal axis of the projectile, which ensures stability and symmetry of the impact of the gas flow on the projectile, and openings 5 or cutouts in adjacent annular protrusions 4 are made non-overlapping, so that the gas stream passing through the hole 5 or the cutout in the previous protrusion, "ran into" the lateral surface of the last the guide projection, not in the hole or recess therein.

In addition to the above, the annular grooves 3 are made perpendicular to the longitudinal axis of the missile projectile, and the number of annular grooves 3 is not less than two and is determined by the requirements of balancing the missile projectile relative to its longitudinal axis. The depth of the annular grooves is made the same or increasing from the back to the side of the nose. It is possible to execute a missile projectile with increasing depth and width of the annular grooves from the back to the side of the bow of the missile. This is done to reduce the turbulence of the gas flow and, accordingly, to reduce the loss of heating the barrel and projectile (bullet).

The holes 5 in the annular protrusions are, as a rule, either round or square. When making cutouts in the annular projections 4, they can be made rectangular in plan. The holes 5 themselves or cutouts in the same annular protrusions 4, it is advisable to perform the same. The holes 5 or cuts in the annular protrusions 4 in the direction from the tail to the side of the nose of the projectile can be made increasing in size.

The radius of the base of the nose part 2, which is made conical, does not exceed the radius of the body 1 of a cylindrical shape minus the distance from the longitudinal axis of the projectile to the nearest edge of the hole 5 or the cutout in the annular groove closest to the nose 2 4. The radius of the nose base part 2, which is made conical, can be selected from the condition of equality of the radius of the nearest annular groove 3.

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 can be an element of the cartridge and when creating excessive pressure of the powder gases in the bullet between the bottom of the barrel 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). In the area adjacent to the outer surface of the cylindrical shape of the projectile (bullet), an area with an increased pressure area of the carrier gas layer on the projectile (bullet) is formed to give it additional acceleration in the direction of the barrel outlet. This zone is formed not by increasing the diameter of the body of a cylindrical shape, but by performing at least one annular groove 3 with the formation of its corresponding ring-shaped protrusions 4. At the same time, at least two holes 5 or a cutout are made in the ring-shaped protrusions 4 which in adjacent annular protrusions 4 are made non-overlapping. As a result, the carrier gas layer first presses on the rear surface of the first annular protrusion 4 from the tail portion, while part of the gases of the carrier gas layer penetrates through holes 5 or cutouts of the annular protrusion 4 located at the rear of the projectile (bullet), and begins to put pressure on the second annular protrusion 4, etc. Moreover, the effect will be maximal if the holes 5 in the adjacent annular protrusions 4 are non-overlapping so that the gas flow passing through the hole 5 or the cutout in the previous annular protrusion 4 “stumbles” into the side surface of the subsequent annular protrusion 4, and not into the hole or cutout him.

The positive effect of the use of the invention, which is associated with an increase in the acceleration speed of a missile projectile, is manifested as follows.

In a missile projectile without ring-shaped protrusions 4 and openings 5 or cutouts in them, the gas flow force F acting on the bullet is:

F _s = S * P,

where - S - the area of the rear of the missile;

P is the pressure of the gases in the barrel.

In the proposed method and the device that implements it, another driving force is added - the aerodynamic drag force of the gas flow passing through holes or cutouts in annular protrusions. Its approximate value can be calculated by the well-known formula of sailing kinetic energy transfer:

F _t = C _^1/2 ρV ² S _t

where C is the coefficient of conversion of the energy of the gas jet into the kinetic energy of the bullet;

ρ is the specific density of the gas duct;

V is the velocity of the gas stream passing through the annular protrusions;

S _t - the total area of the annular protrusions that inhibit the gas flow.

The total driving force will be equal to the sum of the pressure force on the back of the projectile and the aerodynamic drag force:

F = F _s + F _t

Figure 3 presents the test results of 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 4 - 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 the bullet of the proposed design.

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, which consists in simplifying the method while increasing the throwing distance and increasing the lethal force of the projectile. In this case, an increase in throwing distance and increase in lethal force is achieved by increasing the area of pressure of the carrier gas layer on the projectile in the region adjacent to the outer surface of the cylindrical shape of the projectile to give it additional acceleration in the direction of the barrel outlet.

Claims (12)

1. The method of dispersal of a missile projectile during firing, according to which preliminary between the bottom of the barrel and the missile projectile with a cylindrical body create excess pressure of the powder gases and form a carrier gas layer in the direction of the rear of the missile projectile to ensure its directed movement to the barrel outlet, characterized in that in the area adjacent to the outer surface of the body of a cylindrical form of a missile projectile, form a zone with an increased pressure area of the carrier gas layer per m detachable projectile to give it additional acceleration in the direction of the barrel outlet. 2. A missile projectile for implementing the method according to claim 1, comprising a cylindrical metal casing, the bow of which is made along the longitudinal axis of the cylindrical metal casing and at the same time as the cylindrical metal casing, while on the surface of the cylindrical metal casing successively along its length at least one annular groove is made perpendicular to the longitudinal axis of the missile projectile with the formation of corresponding annular protrusions, distinct yuschiysya in that each of the annular projections formed at least two openings, wherein the openings formed in the respective annular projections are arranged at equal distances from one another and from the longitudinal axis of the device and the openings in the adjacent annular ledges made non-overlapping. 3. A missile projectile according to claim 2, characterized in that the depth of the annular grooves is made the same. 4. A missile projectile according to claim 2, characterized in that the number of holes or cuts made in the respective annular protrusions is equal to two, or three, or four. 5. A missile projectile according to claim 2, characterized in that the depth of the annular grooves is made increasing from the back in the side of the bow of the missile. 6. A missile projectile according to claim 2, characterized in that the annular grooves are made perpendicular to the longitudinal axis of the missile projectile. 7. A missile projectile according to claim 2, characterized in that the holes or cutouts in the annular protrusions are made the same. 8. A missile projectile according to claim 2, characterized in that the holes or cutouts in the annular protrusions in the direction from the tail to the bow of the missile are made increasing in size. 9. A missile projectile according to claim 2, characterized in that the holes in the annular protrusions are made either round or square. 10. A missile projectile according to claim 2, characterized in that the cutouts in the annular protrusions are rectangular in plan. 11. A missile projectile according to claim 2, characterized in that the radius of the base of the bow, which is made conical, does not exceed the radius of the body of a cylindrical shape minus the distance from the longitudinal axis of the device to the nearest edge of the hole or cut in the closest to the bow ring groove. 12. A missile projectile according to claim 2, characterized in that the radius of the base of the bow, which is made conical, is equal to the radius of the nearest annular groove.

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