RU2135945C1 - Method for fire by shell and round - Google Patents

Abstract

FIELD: artillery equipment. SUBSTANCE: method consists in shooting of shell and supply of optically transparent working gas to the external peripheral surface. The round has a shell with through holes connected by a passage to the source of optically transparent gas made in its body around the edges of the cross-section. The starting device of the working gas source is engageable with the start transducer. EFFECT: reduced time of target hitting and increased area of hitting without any increase of unmasking factors. 5 cl, 3 dwg

Description

 The invention relates to military equipment, in particular, to methods of firing shells, as well as to shots that implement these methods.

 A known method of firing a rocket (projectile) [1], which consists in firing a rocket (projectile) and implemented when firing a shot with a guided missile (projectile) "Acre" and a sleeve with a propelling charge (firing device).

 The disadvantage of this method and the shot is that the rocket (projectile) during flight experiences aerodynamic drag, in which there is also a component of the frictional resistance. The presence of a large aerodynamic drag is accompanied by a decrease in both the flight speed of the rocket (projectile) and a decrease in the possible firing range (range of its flight), i.e. increasing the time to destroy the target and reducing the possible zone of its destruction. Efficiency is deteriorating. Especially significant is the decrease in the flight speed of the rocket (projectile), when the distance between the launch site and the target (enemy) is insignificant (about 1 -1.5 km). A decrease in speed leads to an increase in flight time to the target and, accordingly, increases (due to the small distance between the launch site and the enemy) the probability of the enemy finding the launch site and return fire, which can lead to defeat of both the calculation and the launcher (or artillery guns), which is being fired. A delay of even a few tenths of a second with a defeat of the target can solve the result of the fire confrontation. But further, if the target will ultimately be hit, then increasing the time for retaliatory actions gives the enemy the opportunity to inflict damage on both the calculation and the launcher. Efficiency is declining. With an increase in the distance between the launch site and the target (adversary), the probability of detecting the launch site and, accordingly, the opening of aimed fire by the enemy (decreases, despite the fact that the projectile’s flight time to the target increases. An increase in flight speed with a given firing range is possible due to an increase in the power of the firing device , but this is accompanied by an increase in weight and dimensions of both the firing device itself and the launcher (artillery gun), which ultimately increases the weight and dimensions of the complex as a whole, thereby reducing its maneuverability on the battlefield and increasing the likelihood of being struck by enemy fire. Also, increasing the flight speed while ensuring a given firing range is possible by increasing the power and operating time of the jet engine (if it is on the projectile), but this is accompanied by an increase in the weight and dimensions of the jet engine, which means that the whole complex as a whole with all the negative consequences. You can increase the speed by reducing the caliber of the projectile, but this is usually accompanied by a decrease in the power of the warhead. For example, the armor penetration of cumulative warheads is directly dependent on the caliber. Efficiency is not increasing.

 Closest to the proposed technical solution is a method of firing a projectile [2], which consists in firing a projectile and delivering a projectile to its outer side surface spaced around the perimeter of the cross section of the shell of the shell of the hot working gas and realized when firing a shot containing a projectile with a firing device and a source of hot working gas in the form of a powder charge with a starting device in the form of a flammable capsule, triggered by pricking it with a talisman, aryayuschego the primer by the action of acceleration forces at the bow and along the perimeter of the projectile body of its cross section provided with through holes communicating with the chamber in which the propellant charge located.

 The disadvantage of this method and the shot is that the supply of hot powder gases from the powder charge to the outer surface of the projectile is accompanied by the emission of smoke, which unmasks the place where the projectile was launched. The likelihood of the enemy finding a place to launch a projectile and opening return fire increases. This can lead to the defeat of both the calculation and the launcher (or artillery gun) with which the firing is being conducted. This is especially significant, as noted above, when the distance between the launch site and the target (enemy) is insignificant (about 1 - 1.5 km). Efficiency is deteriorating.

 The objective of the invention is to increase efficiency by reducing the time to hit the target and increase the possible zone of its defeat without increasing the unmasking factors.

 The problem is solved in the method of firing a projectile, which consists in firing a projectile and feeding during the flight of the projectile to its outer side surface spaced along the perimeter of the cross section of the shell of the working gas shell, so that during the flight of the projectile the working gas is supplied optically transparent, while the working gas supply optically transparent gas on the outer surface of the projectile can produce during the control time relative to the time of launch, and in a shot containing a projectile with a firing device and a working gas source with a starting device, while through the openings connected to a working gas source, the working device of the working gas source interacts with the start sensor, the working gas source is made in the form of an optically transparent source gas, while the source of the working optically transparent gas can be made in the form of a cylinder with a working optically transparent gas, and its starting device in the form of an electromagnetic th valve, and the channel connecting the source of the working optically transparent gas with through holes in the shell of the projectile can also be made in the form of a gap between the internal elements of the projectile.

 A positive effect is achieved by increasing the speed of the projectile and the possible firing range with increasing stealth of combat work.

 This technical solution is illustrated by the drawing (figure 1, 2, 3). In FIG. 1 shows a shot 1 containing a projectile 2 with a firing device 3. The firing device in the case shown in the drawing is made in the form of a jet engine 4, but it can also be in the form of a gas generator, a powder charge in a sleeve (when firing a projectile from the barrel) or a piston under the action of compressed gas firing a projectile, etc. The projectile is provided with a source 5 of working optically transparent gas with a triggering device 6, and through holes 9 are spaced around the perimeter 8 of its cross section in the shell body 7 of the projectile, connected to a source of working optically transparent gas by a channel 10, and the starting device of the working optically transparent gas source interacts with start sensor 11. A source of working optically transparent gas, as shown in FIG. 1, 2, 3, can be made in the form of a cylinder 12 with a working optically transparent gas (compressed or liquefied), for example, nitrogen or air, and its starting device - in the form of an electromagnetic valve 13. It can also be made in the form of a chemical generator generating a working optically transparent gas, for example, by reacting sodium bicarbonate with an acid. In this case, the starting device provides the operation of the chemical generator. The source of the working optically transparent gas can also be made in the form of an air intake device in which it is advisable to have one air intake located along the axis of the projectile. At the same time, the entrance to the air intake device during operation and storage (before firing) can be either constantly open or closed with a removable plug. The air intake can also be closed by a plug automatically fired off or moved to the side with the provision of "opening" the passage channel of the air intake device before firing or at the initial moment of the projectile flight. In this case, the mechanism of automatic "opening" of the air intake device serves as a starting device. Channel 10 exiting from the source of the working optically transparent gas has branches 14 going to the through holes in the shell of the projectile. In this case, branches can go both to each through hole, and, for example, as shown in FIG. 3, to several at once (two, three, etc.), depending on the particular design. It is most advisable to group through holes two in a group, as this ensures the most uniform distribution of the incoming working optically transparent gas between them. Through holes 9 in the shell of the projectile can be made in the form of round holes, and, for example, as shown in FIG. 2, 3, in the form of slots 15 located on the larger side around the perimeter of the cross section of the projectile. The implementation of through holes in the form of slots gives a more uniform distribution of the working optically transparent gas on the surface of the projectile when it is supplied during the flight. As a start sensor (with an electric trigger system for a trigger device of a source of working optically transparent gas), for example, as shown in FIG. 1, 2, 3, inertial contactor 16, triggered from the starting overload during the launch of the projectile. It can also be made in the form of a gas contactor, closing its working contacts from the action of powder gases of a firing device. In the case of an electric actuation system of a firing device, the start sensor can also be in the form of a branch from its activation circuit and a source of working optically transparent gas (cylinder, air intake device and) to the starting device (solenoid valve, “opening” system of the air intake device, etc.) etc.), thereby ensuring their joint operation. It should be noted that when firing a projectile from the barrel, it is necessary to give a time interval for the projectile to travel through the barrel relative to the projectile leaving the barrel and only after that “give a command” to trigger the trigger device of the working source of optically transparent gas. When the source of the working optically transparent gas is in the form of an air intake device with a constantly open inlet, the function of its starting device with a start sensor in this case is a firing device that gives a projectile power impulse and accordingly causes it to move forward (projectile launch), i.e. with the beginning of the projectile’s flight, the optically transparent working gas (air) receives automatically from its source (air intake device). The channel 10 connecting the source of the working optically transparent gas with through holes in the shell of the projectile, if there are no through holes in the shell of the shell, except those to which this channel is connected, can be made in the form of a gap 17 between the internal elements 18 of the shell.

 The shot works as follows. A projectile with a firing device is installed on a launcher or in the barrel of an artillery gun (depending on the design of the shot) and is prepared for firing. Next, they give a command to shoot and use a firing device. The projectile receives a power impulse from the firing device (starting engine, gas generator, powder charge in the sleeve, etc.) and begins to move forward. Before starting the projectile or at the initial moment of its flight, the starting device for the source of the working optically transparent gas is turned on and the working optically transparent gas is supplied through the channel to the outer surface of the projectile. The working optically transparent gas entering the outer surface of a flying projectile envelops the projectile, creating a “lubricating” layer between the air flowing around the projectile and the projectile itself, which makes it possible to reduce friction. In this case, the working optically transparent gas entering the outer surface of the projectile does not unmask the launch site. After the projectile has flown a distance of the order of 1 - 1.5 km, counted in the control time, i.e. the time during which the projectile is guaranteed to fly this distance, the supply of working optically transparent gas to the side surface of the projectile can be stopped.

 In the shot, supplying the projectile with a source of working optically transparent gas with a starting device, and in the shell of the projectile through holes perforated along the cross-section, making through holes connected by a channel to a source of working optically transparent gas, as well as the interaction of the source of working optically transparent gas with a start sensor allows not only reduce friction resistance, which reduces the total aerodynamic drag, but also does not unmask the launch site, increasing the stealth of firing. At the same time, the velocity of the projectile rises (the time for hitting the target decreases) and the possible firing range increases (the possible zone of hitting the target increases). Efficiency is increasing. The supply of a working optically transparent gas to the outer surface of the projectile during the control flight time, which corresponds to the guaranteed projectile passage of a distance of the order of 1 - 1.5 km from the launch site, makes it possible to increase the velocity of the projectile in the area most dangerous from the point of view of the possible detection by the enemy of the launch site, and accordingly, reduce the time for its possible response (opening fire or shelter behind any protective structure, terrain, etc.). Winning in time at this distance (of the order of 1 - 1.5 km), even in a few tenths of a second, can decide the outcome of the match. With a distance between the launch site and the target of more than 1 - 1.5 km, despite the increase in time for response, the probability of the enemy finding the projectile launch site, due to the increased distance, decreases. Recalculation of the distance during which the projectile is guaranteed to fly 1-1.5 km from the launch site can significantly simplify the control system for the operation of the source of the working optically transparent gas. This makes it possible to avoid the need to supply the complex with devices that are often very complex and cumbersome, providing a measure of the distance flown by the projectile from the moment of launch. In addition, elements of such a device (for example, a laser rangefinder with a transmitter for stopping the supply of working optically transparent gas) often need to be located not only on the projectile, but also on the launcher, which increases its weight and dimensions with all the ensuing negative consequences. When a device is located on the projectile that measures the distance traveled by it, the dimensions and weight of the projectile also significantly increase, which affects its technical characteristics and, accordingly, efficiency. Providing the supply of working optically transparent gas for a control time, guaranteeing a projectile to fly a distance of the order of 1 - 1.5 km, can be ensured, for example, by the volume of working optically transparent gas (compressed or liquefied) in the cylinder, or the operating time of the chemical a generator that produces a working optically transparent gas, and is the simplest, which increases reliability, and therefore, efficiency. At the same time, the required dimensions and weight of the source of the working optically transparent gas (cylinder, chemical generator, etc.) are reduced, which reduces the dimensions and weight of the entire projectile, further increasing efficiency. Nitrogen, carbon dioxide, air, etc., as well as a special gas mixture that reduces friction resistance can be used as a working optically transparent gas. The implementation of the source of the working optically transparent gas in the form of a cylinder with the working optically transparent gas makes it possible to use a special gas mixture as the working optically transparent gas, which reduces friction resistance, and therefore even further increase the velocity of the projectile, which increases efficiency. Through holes in the shell of the projectile, connected to a source of working optically transparent gas, it is advisable to place as close as possible to the front end of the projectile. This makes it possible to cover a large part of the side surface of the projectile with a “lubricating” layer of a working optically transparent gas, and hence reduce friction. Efficiency is increasing. The implementation of the channel connecting the source of the working optically transparent gas with through holes in the shell of the projectile in the form of a gap between the internal elements of the projectile greatly simplifies the proposed design of the projectile, which increases its reliability, and hence its efficiency.

 The proposed technical solution allows you to increase efficiency by reducing the time to hit the target and increasing the possible zone of its destruction, which is achieved by increasing the speed of the projectile and the possible firing range with increased stealth of combat work.

Sources of information:
1. Latukhin A.N. Anti-tank weapons. - M .: Military Publishing, p. 230-234.

 2. USA, patent, 3345948 F 42 B 13/02, 10.10.67.

Claims (5)

 1. The method of firing a projectile, which consists in firing a projectile and supplying a projectile to its outer side surface spaced around the perimeter of the cross section of the shell of the working gas shell, characterized in that the working gas is supplied optically transparent during the flight of the projectile.  2. The method of firing a projectile according to claim 1, characterized in that the working optical optically transparent gas is supplied to the outer side surface of the projectile during the control flight time relative to the moment of its launch.  3. A shot containing a projectile with a firing device and a source of working gas with a starting device, and through holes perforated along the perimeter of its cross section in the shell of the projectile are made through holes connected to the working gas source by a channel, the working gas source starting device interacting with a start sensor, characterized in the fact that the source of the working gas is made in the form of a source of optically transparent gas.  4. A shot according to claim 3, characterized in that the source of the working optically transparent gas is made in the form of a cylinder with the working optically transparent gas, and its starting device is in the form of an electromagnetic valve.  5. The shot according to claim 3 or 4, characterized in that the channel connecting the source of the working optically transparent gas with through holes in the shell of the projectile is made in the form of a gap between the internal elements of the projectile.

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