RU2211436C2 - Powder charge for recoiless gun - Google Patents

Abstract

FIELD: military equipment, applicable for recoiless guns. SUBSTANCE: the powder charge for recoiless gun (modification 1), located in the barrel between the nozzle and the shell, includes the powder components positioned in parallel with the bore line and made in the form of cylindrical rods with a central hole closed on the side of the shell and open on the side of the nozzle. The powder charge for recoiless gun (modification 2), located in the barrel between the nozzle and the shell, includes the powder components that are made of cylindrical rods with a through channel open on both sides by bending them in the middle so that the formed halves of the rods are in parallel with each other and a positioned in parallel with the bore line with open through channels on the side of the nozzle. EFFECT: improved internal ballistic characteristics. 6 cl, 4 dwg

Description

 The invention relates to military equipment and can be used for recoilless guns and grenade launchers, as well as as a starting accelerator for rockets launched from a pipe.

 As a throwing charge for recoilless guns, as a rule, a powder charge is used, consisting of powder grains with a thin burning arch (see M. E. Serebryakov. Internal ballistics of barrel systems and powder rockets. M.: Oborongiz, 1962). A charge with a thin burning vault of powder grains allows for a high degree of combustion, however, the powder gases have a high maximum pressure.

 Known recoilless gun with opposing mass (see FR 2567258, IPC F 41 F 17/12, 1/00, 3/02, F 42 V 5/05, 5/18). The use of an opposing mass allows to reduce the maximum pressure of the powder gases, however, the charge structure is complicated and its weight is increased.

 Closest to the claimed one is "Gunpowder charge of an artillery system with increased firing range" (see RU 2075030, IPC F 42 B 5/05, 03/10/1997), made in the form of a set of powder checkers, booked on the outer surface with cylindrical channels and located in a recoilless gun between the projectile and the nozzle. A disadvantage of the known charge is that the powder bombs during the shot are ejected through the nozzle by a gas stream, while the ballistic characteristics of the charge are reduced.

 The technical result of the present invention is to improve the ballistic characteristics of the powder charge for recoilless guns by gas-dynamic retention of the powder elements in the barrel during the shot.

 The indicated technical result is achieved in that the powder charge located between the nozzle (1) and the projectile (2) consists of powder elements having the form of a cylindrical rod with a central channel (3). The powder charge is characterized in that the powder elements are parallel to the axis of the barrel (4) of the recoilless gun, and the central channel (3) is closed from the side (5) facing the projectile (2) and open from the side (6) facing the nozzle (1) recoilless guns. This design of the powder elements ensures the outflow of powder gases when fired from the central channel (3) in the direction of the nozzle (1). This creates a reactive force acting on the powder elements in the direction of the projectile (2) and preventing the ejection of powder elements through the nozzle (1).

 To increase the force acting on the powder element and directed away from the nozzle (1), as well as to provide a progressive gas inlet during charge burning, it is proposed to cover the outer surface of the powder elements at least partially from the side (5) facing the projectile (2), booking agent (7).

 To increase the force acting during the shot on the powder element and directed from the nozzle (1), it is proposed that the powder elements be made in such a way that the end surface of the rods at the open side of the central channel is formed by one or more surface sections (8) located at an acute angle to channel axis (3). Thus, the bottom resistance of the rods decreases when flowing around with powder gases.

 Another way to achieve this technical result is that the powder charge located between the nozzle (1) and the projectile (2) consists of powder elements made of a cylindrical rod with a through channel (3) open on both sides. In this case, the powder element is made by bending it in the middle so that the half-bars formed in this case are parallel to each other and are parallel to the axis of the barrel (4) with an open through channel (3) from the nozzle side (1).

 To increase the force acting during the shot on the powder element and directed away from the nozzle (1), as well as to provide a progressive gas intake during charge burning, it is proposed to cover the outer surface of the powder elements, at least partially from the bent side (5), with an armor compound ( 7).

 To increase the force acting during the shot on the powder element and directed from the nozzle (1), it is proposed that the powder elements be made in such a way that the end surface of the curved rods at the open side of the central channel is formed by one or more surface sections (8) located at an acute angle to the axis of the channel. Thus, the bottom resistance of the rods decreases when flowing around with powder gases.

 To create a force impulse directed to the powder charge from the nozzle (1), when ignited, the igniter (9) should be placed between the powder charge and the nozzle (1).

 The powder charge is widely known, consisting of powder elements having the form of a cylindrical rod with a central channel open on one side and closed on the other, the so-called charge of the "brush" structure. In a known charge, the powder elements are rigidly glued to the bottom of the rocket engine chamber, and their retention in the chamber during engine operation is carried out by mechanical coupling. The difference of the claimed powder charge from the known charge of the "brush" design is that the powder elements are not rigidly connected to the charging chamber and to each other. This allows you to abandon the additional camera, to which the powder elements are glued, and therefore, to facilitate the charge and simplify its manufacture.

 The essence of the claimed invention is shown in four figures.

 Figure 1 shows a powder element in the form of a cylindrical rod with a central channel (3) open from the side (6) facing the nozzle and closed from the side (5) facing the projectile.

 To increase the force acting on the powder element and directed from the nozzle (1), as well as to provide a progressive gas intake during the shot, the powder rod from the closed end (5) of the central channel (3) is at least partially covered with an armor compound (7 )

 To increase the force acting during the shot on the powder element and directed from the nozzle (1), by reducing the bottom resistance when the powder flows around the rod with powder gases, the end surface at the open side (6) of the central channel (3) is formed by one or more surface sections (8 ) located at an acute angle to the axis of the channel (3).

 Figure 2 shows the powder charge for recoilless guns located between the nozzle (1) and the projectile (2). The powder elements are made in the form of rods with a central channel (3) located parallel to the axis of the barrel (4). The central channel (3) is made closed from the side (5) facing the projectile (2), and open from the side (6) facing the nozzle (1). The powder bar on the closed side (5) of the channel (3) is at least partially covered with an armor compound (7). The end surface of the rod at the open side (6) of the central channel (3) is formed by one or more surface sections (8) located at an acute angle to the axis of the channel (3). The igniter charge (9) is located between the nozzle (1) and the powder charge. The volume between the nozzle (1) and the powder charge is indicated by (10). The volume between the projectile (2) and the powder charge is indicated by (11).

 Figure 3 shows a powder element made of a cylindrical rod with a through channel (3) by bending it in the middle.

 To increase the force acting on the powder element and directed away from the nozzle (1), as well as to provide a progressive gas intake during the shot, the powder bar from the bent side (5) is at least partially covered with an armor compound (7).

 To increase the force acting during the shot on the powder element and directed from the nozzle (1), by reducing the bottom resistance when the powder flows around the rod with powder gases, the end surface at the open side (6) of the central channel (3) is formed by one or more surface sections (8) located at an acute angle to the axis of the channel (3). The lower part of the curved portion of the powder element is indicated by (12).

 Figure 4 shows the powder charge for recoilless guns located between the nozzle (1) and the projectile (2). The charge consists of powder elements made of a cylindrical rod with a through channel (3) open on both sides. In this case, the powder element is made by bending it in the middle so that the half-bars formed in this case are parallel to each other and are parallel to the axis of the barrel (4) with an open through channel (3) from the nozzle side (1).

 To increase the force acting on the powder element and directed away from the nozzle (1), as well as to provide a progressive gas intake during the shot, the powder bar from the bent side (5) is at least partially covered with an armor compound (7).

 To increase the force acting during the shot on the powder element and directed from the nozzle (1), by reducing the bottom resistance when the powder flows around the rod with powder gases, the end surface at the open side (6) of the central channel (3) is formed by one or more surface sections (8) located at an acute angle to the axis of the channel (3). The lower part of the curved portion of the powder element is indicated by (12). The igniter charge (9) is located between the nozzle (1) and the powder charge. The volume between the nozzle (1) and the powder charge is indicated by (10). The volume between the projectile (2) and the powder charge is indicated by (11).

 The powder charge according to claim 1 of the claims (figure 2) works as follows.

 After the initiation pulse is supplied to the igniter (9), it starts burning. The gases formed during this process impart a force impulse directed from the nozzle to the powder elements and ignite them. Powder elements burn on a surface not covered by an armor compound (7), including on the channel surface (3). The powder gases flowing from the channel (3) create a reactive force directed from the nozzle (1), thereby preventing the ejection of powder elements from the barrel channel (4).

 If the surface (8) of the powder element forms an acute angle with the axis of the channel (3), its flow around it improves and pressure on this surface increases, preventing the ejection of powder elements from the barrel.

 Under the influence of the pressure of the powder gases, the movement of the projectile (2) begins and the volume (11) between the projectile and the powder charge increases. Powder gases filling this volume flow around the powder elements, dragging them along with them.

 The gases generated during combustion flow out of the nozzle (1). With a constant combustion surface and a constant volume of projectile space in the barrel, a constant equilibrium pressure of the powder gases is established. The decrease in gas pressure caused by the increase in the volume of the projectile space is compensated by the progressive gas inlet, which is provided by the reservation (7).

 Thus, the inventive powder charge for a recoilless gun provides acceleration of the projectile (2) with constant acceleration, while achieving the maximum muzzle velocity at a given maximum pressure of the powder gases, or the minimum gas pressure at a given value of the muzzle velocity.

 The performance of the claimed powder charge follows from the limiting case when the entire outer surface of the powder elements is covered with an armor compound (7). In this case, during the shot, combustion occurs only along the surface of the central channel (3), from where the gases flow into the volume (10) located between the powder charge and the nozzle (1). In the volume (11) located between the projectile (2) and the powder charge, the gases flow from the volume (10), therefore, the gas pressure in the volume (10) is higher than in the volume (11). Thus, on the powder elements, in addition to the reactive force from the gases flowing out of the channel (3), the pressure difference in the volumes (10) and (11) acts, that is, the forces directed from the nozzle (1) act, which ensures that the powder charge is in bore during the entire period of the shot.

 The necessary fraction of the outer surface of the powder elements coated with the armor composition (7) depends on the ballistic characteristics of the particular shot (mass of the projectile (2), mass of the powder charge, thickness of the burning vault of the powder element, channel diameter (3), maximum pressure of the powder gases, channel area barrel (4), the critical section area of the nozzle (1)).

 The powder charge according to claim 4 of the claims (figure 4) works as follows.

 After the initiation pulse is supplied to the igniter (9), it starts burning. The gases formed during this process impart a force impulse directed from the nozzle to the powder elements and ignite them. Powder elements burn on a surface not covered by an armor compound (7), including on the channel surface (3). The powder gases flowing from the channel (3) create a reactive force directed from the nozzle (1), thereby preventing the ejection of powder elements from the barrel channel (4).

 If the surface (8) of the powder element forms an acute angle with the axis of the channel (3), its flow around it improves and pressure on this surface increases, preventing the ejection of powder elements from the barrel.

 Under the influence of the pressure of the powder gases, the movement of the projectile (2) begins and the volume (11) between the projectile and the powder charge increases. Powder gases filling this volume flow around the powder elements, dragging them along, including interacting with the lower part of the curved section of the powder element (12). Thus, an additional force arises that prevents the ejection of powder elements from the barrel.

 The gases generated during combustion flow out of the nozzle (1). With a constant combustion surface and a constant volume of projectile space in the barrel, a constant equilibrium pressure of the powder gases is established. The decrease in gas pressure caused by the increase in the volume of the projectile space is compensated by the progressive gas inlet, which is provided by the reservation (7).

 Thus, the inventive powder charge for a recoilless gun provides acceleration of the projectile (2) with constant acceleration, while achieving the maximum muzzle velocity at a given maximum pressure of the powder gases, or the minimum gas pressure at a given value of the muzzle velocity.

 The performance of the claimed powder charge follows from the limiting case when the entire outer surface of the powder elements is covered with an armor compound (7). In this case, during the shot, combustion occurs only along the surface of the central channel (3), from where the gases flow into the volume (10) located between the powder charge and the nozzle (1). In the volume (11) located between the projectile (2) and the powder charge, the gases flow from the volume (10), therefore, the gas pressure in the volume (10) is higher than in the volume (11). Thus, on the powder elements, in addition to the reactive force from the gases flowing out of the channel (3), the pressure difference in the volumes (10) and (11) acts, that is, forces directed from the nozzle (1) act, which ensures the presence of the powder charge in the channel barrel during the entire period of the shot.

 The necessary fraction of the outer surface of the powder elements coated with the armor composition (7) depends on the ballistic characteristics of the particular shot (mass of the projectile (2), mass of the powder charge, thickness of the burning vault of the powder element, channel diameter (3), maximum pressure of the powder gases, channel area barrel (4), the critical section area of the nozzle (1)).

Claims (6)

 1. The powder charge for recoilless guns, including powder elements with a central channel located in the barrel between the nozzle and the projectile, characterized in that the powder elements are parallel to the axis of the barrel and made in the form of cylindrical rods with a central channel closed from the side of the projectile and open with side of the nozzle.  2. The powder charge for recoilless guns according to claim 1, characterized in that the outer surface of the rods from the closed end of the central channel is at least partially covered with an armor compound.  3. The powder charge for recoilless guns according to claim 1, characterized in that the end surface of the rods at the open side of the central channel is formed by one or more surface sections located at an acute angle to the axis of the channel.  4. The powder charge for recoilless guns, including powder elements located in the barrel between the nozzle and the projectile, characterized in that the powder elements are made of cylindrical rods with a through channel, bent in the middle so that the half bars formed in this case are parallel to each other and are parallel the axis of the barrel, the through channel of which is open from the nozzle side.  5. The powder charge for recoilless guns according to claim 4, characterized in that the outer surface of the rods from the curved side is at least partially covered with an armor compound.  6. The powder charge for recoilless guns according to claim 4, characterized in that the end surface of the rods at the open through channels is formed by one or more surface sections located at an acute angle to the axis of the channel.

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