RU2062428C1 - Portable grenade launcher - Google Patents

Abstract

FIELD: weapons. SUBSTANCE: invention refers to design of portable grenade launchers of single usage. Containers with grenade launcher shots are connected in pairs to shooting device and are turned through 180 deg relative to each other. Reaction engine of shot is manufactured separable from grenade and container with launch and is provided with gas lock on outer surface. Throttle holes made in it communicate combustion chamber to gas lock and space of container behind grenade. Grenade is equipped with device to spin fluid or paste-like charge after shooting and anti-rebound elements to prevent rebounding of grenade from obstacles with strong lining. Tangential laminated stabilizers are put with skew on to rear skirt of grenade. EFFECT: increased reliability of target hitting with reduction of dimensions, simplified design. 8 cl, 11 dwg

Description

 The invention relates to the field of defense technology and can be used in the development of portable non-return grenade launchers of single use.

 Known grenade launcher from British patent N 1288732, CL F FOR, F 42 B 9/12, publ. 09/13/72, which is an analogue of the proposed device. It consists of a launch tube, to the back of which a hook is connected to a container with a rocket placed inside it, including a warhead with a conventional cumulative or fire charge, a rocket engine with a solid fuel charge, a nozzle and a stabilizer made, for example, in view of the cylindrical part of the rocket engine housing. In this case, a missile with its front part enters the launch tube, and the solid fuel rocket engine is placed in a container rigidly fastened to the launch tube.

 A prerequisite for this and similar grenade launcher design is that the working time of the powder charge of the engine is limited by the longitudinal dimensions of the launch tube. The charge should burn out before the exit section of the nozzle exits the launch tube.

 The disadvantages of this design of the grenade launcher are the large longitudinal dimensions in the combat position, due to the above condition and the sequential arrangement of the launch tube and the container with the projectile, the inability to re-shot from one installation, the low quality factor of the warheads when using liquid and paste-like fillings due to the large impact loads an ampoule, as well as the incomplete use of the stored energy of liquid equipment when rupturing an ammunition.

 To some extent, the shortcomings are eliminated in the 4-barrel hand grenade launcher XM 191 USA, described in the journal "Foreign Military Review" publishing house "Red Star", Moscow, 1975. N 2 February, pp. 47-48, taken as a prototype of the invention.

The XM 191 grenade launcher is a wearable complex and has four barrels located in one rectangular case and rigidly interconnected by clips. A removable clip with 4 rocket-propelled grenades is attached to the body. Incendiary grenade contains an ampoule filled with a self-igniting fire mixture, and a solid fuel starting jet engine. The impact mechanism of a mechanical type grenade launcher has a trigger and ratchet mechanism, providing a consistent rotation of the projectile by 90 ^o and pricking grenade capsules. The grenade launcher is equipped with an optical sight, which provides targeted shooting at point targets at distances of up to 200 m, and in areas of up to 730 m.

 The disadvantage of the described design of the grenade launcher is the insufficient reliability of hitting the target with a rather significant size and complexity of the structure, which is explained by the following considerations.

 The four-barreled grenade launcher does not allow the use of grenades with a significant content of combat equipment, for example, a large-detonating mixture, sufficient to destroy such military structures as the bunker, or to destroy an infantry fighting vehicle or light tank participating in modern combat.

 In addition, a grenade launcher with 4 barrels is not required in modern combat for the following reasons. Usually the first shot does not always hit a small target, because it is difficult with simple sighting devices to take into account all the factors affecting the flight path of a grenade: wind speed, distance to the target, air temperature, terrain, etc. and therefore the first shot is usually sighting. The target is hit with sufficient reliability only by the second shot. Subsequent shots practically do not increase the probability of hitting targets, because firing accuracy is already beginning to be affected by the technical dispersal of grenades. Everything described above is true for the defeat of the second, third, etc. goals. However, after two shots and hitting the target, you have to wear the two remaining empty barrels, because they are connected by an inextricable bond. The above reasoning is also true in the event of a hit by the first shot.

 In addition, the described grenade launcher has significant variations in the muzzle velocity of a grenade in the temperature range of use due to the lack of a device for compensating for temperature fluctuations in the size of nodes and the energy of the powder charge, which also reduces the reliability of hitting the target.

 The grenade of the described grenade launcher with liquid contents has significant passive weight due to the need to ensure its strength during firing - the liquid during firing will unload the ampoule walls due to inertia forces and, if their strength is insufficient, push it into the barrel (container), and this, in turn, reduces reliability of hitting a target.

 The aim of the present invention is to increase the reliability of hitting a target while reducing the size and simplifying the design.

This goal is achieved in that the design of the proposed grenade launcher provides the following structural differences:
launch containers are placed so that their aiming devices are directed to one side and placed on opposite sides of the complex, while the container is equipped with two folding pistol-type handles, each shot consists of a grenade and a jet engine with a combustion chamber, and around the junction of the grenade and the jet free volume is formed in the engine in the container, the grenade has a liquid or pasty charge and is equipped with a device for twisting the charge during rotation of the grenade and a device that prevents when the impact is hit by a barrier, and the jet engine is installed with the possibility of separation from the grenade and the container during firing, it is equipped with a gas shutter on the outer surface and is made with throttle openings connecting the combustion chamber to the gas shutter and free space around the junction of the grenade and the jet engine;
container connection elements are placed in two places spaced along the length and are represented by pins with their fixing elements, for example, radial protrusions and a longitudinal groove symmetrical to them at the end of each pin, installed in the holes of the eyes made two on the tops of the protrusions having the same shape and size and displaced relative to the horizontal plane passing through the axis of symmetry of the container, in one direction by the thickness of the eye, while at the top of each protrusion at the base of the farthest from the axis of the container the eyelets made a longitudinal groove under the eye of the reciprocal container, and the protrusions on each container are fixed on the opposite side to its sighting device;
the gas shutter on the jet engine is made in the form of an annular lowering, and the throttle hole connecting it to the combustion chamber is located on one side at the location of the igniter of the powder charge of the jet engine, and on the other coaxially to the radial hole made in the container wall and connecting the gas shutter to afterburner mounted on the side surface of the container from the outside against the firing device and containing a percussion igniter capsule and an additional powder poison;
the jet engine is equipped with a pressure regulator located in its nozzle block and made in the form of a perforated support with a membrane on which there is an elastic heat-insulating coating on the side of the powder charge, for example, a rubber layer, while the perforation of the support on the membrane side is chamfered and the membrane is made of plastic metal, for example copper;
the grenade is made in the form of a thin-walled ampoule, the centering belts of which have a box-shaped section open to the charge of the grenade, and are lowered relative to the inner surface of the container providing a profile gap between them for the passage of powder gases, while a glass with an igniter attached to its bottom is installed along the axis of the ampoule explosive charge and contact fuse;
The device for twisting the grenade charge is made in the form of protrusions on the outer surface of the glass with an ignition-explosive charge and fuse and oblique, stabilizing the grenade in flight plates mounted on a hollow cylindrical skirt attached to the bottom of the grenade from the outside from the side of the jet engine, while in the wall of the skirt bypass windows are made between the stabilizing plates and the bottom of the grenade, and stampings are made on the stabilizing plates, the tops of which are plates in the folded position of the contour ct with the inner surface of the container;
the device of the anti-recoil grenade from the obstacle is made in the form of a central rod with a predominantly conical thickening protruding beyond the hollow ballistic tip of the grenade, and the pressing mass, represented by a glass with an ignition-explosive charge, a thin-walled skirt with stabilizing plates and elements for their fastening to the bottom of the grenade;
the firing device is placed on the side of the container opposite to the sighting device and is represented by a V-shaped torsion spring mounted on the axis of the rear pistol grip and a striker located above the handle between the guiding cylindrical pin and the trigger sear, and an annular groove is made on the striker with conical surfaces at the ends, between which the shoulder of the V-shaped spring is placed, covering the firing pin in the groove zone, and two transverse grooves, ne the middle walls of which interact with the trigger’s sear and provide a platoon when the sear is in the groove closest to the annular groove, and the safety cock is in the far, while the rear walls of the grooves are provided with horizontal protrusions for the retaliation groove of the sear. The proposed design of a portable grenade launcher complex is illustrated by a drawing of a portable non-return grenade launcher, which shows: in FIG. 1 a general view of a grenade launcher complex (ammunition), consisting of two single-use recoilless grenade launchers: in FIG. 2 general side view of the ammunition; in FIG. 3 type of ammunition from the target; in FIG. 4 junction of containers in the ammunition; in FIG. 5 container with a shot in the context; in FIG. 6 jet engine with a gas shutter, a pressure regulator, nodes connecting it with a grenade and a container; in FIG. 7 grenades in a container in a section; in FIG. 8 grenade upon impact on an obstacle; in FIG. 9 - trigger mechanism of the grenade launcher in the stowed position; in FIG. 10 - trigger mechanism of a grenade launcher after a shot; in FIG. 11 is a section along AA of FIG. 10.

 The wearable grenade launcher system consists of a container 1 grenade 2, a jet engine 3, a firing device 4, an aiming device 5, a carrying device 6, an eye 7 with a protrusion 8 and a groove 9, the width and depth of which are equal to the thickness and height of its protrusion, as well as the pin 10 connecting the eyes.

 The gas shutter is formed by an annular lowering 11 on the jet engine housing and is connected to its internal cavity by a radial hole 12. The front throttle hole 13 connects the combustion chamber with a free volume around the junction of the grenade and the jet engine. The engine with a grenade is connected by an expanding collet 14 with grippers 15 held by a piston 16 in the annular groove 17 of the engine, around the front throttle hole. The engine, in turn, is secured in the container with leaf springs 18 mounted opposite the nozzles 19. The engine pressure regulator is a perforated support 20 in the nozzle block, closed by a copper membrane 21, which is coated with a heat-insulating coating (rubber) 22. The perforation on the membrane side is dulled by chamfers 23. In the afterburner 24 is placed on the igniter capsule 25 with an additional powder charge 26.

 The grenade is installed in a container with a profiled gap 27, filled with a multicomponent charge 28 of a liquid or pasty state and contains a thin-walled body 29 with centering belts 30 in the form of box-shaped rings filled with charge. In the bottom of the case there is a glass 31 with an ignition-explosive charge 32 and pressing masses in the form of a thin-walled skirt 33 with bypass holes 34 and a conical insert 35. On the outer surface of the glass, projections 36 are made, and tangential skid-mounted stabilizers 37 with stampings 38 are fixed on the skirt. ballistic tip 39 posted by the Central rod 40 with a tapered front end.

 Each container is equipped with two pistol-type folding arms 41 with spring-loaded latches 42. The firing device handle, located on the opposite side of the sighting device, is in contact with the V-shaped combat spring 43 to ensure it is cocked, and is fixed in front of it in a rigid case with a safety bracket 44 the trigger 45 and the fuse against accidental shot 46. In this case, the trigger with the upper shoulder, acting as a sear, keeps the drummer cocked. A V-shaped spring covers the firing pin along the annular groove 48 with the possibility of contact with the conical surfaces 49 at its ends. The drummer is located between the guides of its movement by a cylindrical pin 50 and the trigger sear 51, mounted in the transverse groove 52 of the hammer, where a horizontal protrusion 53 is made on the back wall under the mating groove 54.

 The operation of the described device is as follows. Before firing, the firing device is cocked, for which they click on the latch 42 and the handle is moved from the stowed position until it is locked in combat. In this case, the spring 43 is twisted and its upper end departs from the front conical surface 49 of the groove of the hammer 47 and begins to press on the opposite conical surface. In this position, the firing pin 47 is kept from moving by the trigger 51 of the trigger 45. For firing a shot, turn the fuse box 46 and press the trigger, disengaging it from the firing pin, which strikes the capsular igniter 25. The igniter capsule in the afterburner 24 ignites an additional gunpowder charge 26, the gases of which ignite the solid fuel charge of a jet engine. Combustion products (powder gases from the engine) expire simultaneously through the nozzle openings 19, the radial throttle hole 12 and the front throttle hole 13. The gases flowing out of the nozzles 19 form a driving force balancing the pressure force of the gases telling the speed of the grenade 2, eject the engine mounts in the container, leaf springs 18 and tear off the sealing cover of the container. Gases flowing through the front throttle aperture 13 create pressure between the grenade and the jet engine and shift the piston 16, which frees the grips of the collet 14, which ensures that the grenade and the jet engine are disengaged at the start of movement without impact and without creating an impulse of dynamic imbalance during firing. Acceleration of the grenade is provided by the pressure of the powder gases in the "bespoke" space. The same pressure produces a braking of the jet engine in a certain billing period until it stops completely before the front cut of the container. Due to the profiled gap 27 formed by stepped centering belts 30, the grenade wall is under the same pressure both from the inside of the charge and from the outside of the powder gases. This allows the ammunition shell to be thin-walled, since the inside created by a liquid or pasty charge 28 under the action of acceleration in the barrel, a large pressure on the walls is compensated by the external pressure of the powder gases. Such a device allows you to increase the charge by reducing the passive weight of the grenade.

 A gas shutter formed by the powder gas flowing out through the throttle aperture 12 and an annular collapse 11 on the outer surface of the engine provides sealing of the "projectile" space from the leakage of powder gases along the engine walls, significantly reduces the pressure spread in the projectile space. And this, in turn, stabilizes the muzzle velocity of a grenade, reduces the mass of the powder charge of the engine, and ultimately increases the accuracy of shooting.

 To accelerate the grenade, both the energy of the jet engine’s movement and the energy of the compressed gas in the “near-shell” space are used, which provides a significant increase in the efficiency of using the powder charge and barrel length with a small momentum of imbalance.

 When the grenade leaves the end of the container, skid-mounted stabilizing plates 37 are opened, which twist the grenade along the trajectory due to the incoming air flow. Under the action of friction between the charge and the walls of the grenade, as well as due to the protrusions 36 on the glass, the charge is untwisted. Due to the fact that the charge is not filled until the volume is completely filled due to the need to compensate for its thermal expansion, during rotation it forms along the axis of the grenade around and in front of the glass 31 with an ignition-explosive charge 32 free axial channel. Since the charge contains light and, as a rule, flammable, as well as heavier fractions (metal additives), the latter are shifted to the outer walls of the grenade under the influence of centrifugal forces. The lighter fractions concentrate around the cup 31. When an obstacle is hit by an inertia force, the rod is introduced into the barrier, and the ballistic tip 39 is deformed, compacting the barrier and preventing the grenade from bouncing due to compression of the barrier material around the rod 40 with a conical front end. In this case, due to inertia forces, the entire column of charge moves to the front end of the grenade, the pressing mass, mounted on the glass, also displaces it to the front end of the grenade along the axial channel free of the mixture. Since the pressing mass is made in the form of spaced parts, its part in the form of a cylindrical skirt and elements of its fastening deforms the thin-walled grenade body to a barrel-shaped form (Fig. 8), compressing it along its length. In this case, a contact fuse is triggered with detonation of the ignition-explosive charge. Since layers of a flammable fraction of the warhead charge are placed directly around it, their reliable ignition and complete combustion occur, which ensures more complete dispersion and initiation of heavy warhead charge fractions throughout the volume.

 If it is necessary to make a second shot, the ammunition is rotated around the longitudinal axis by 180, corrections are introduced for the first sighting shot and a second shot is fired. In case of hitting the target with one shot, the shot container is undocked and, if necessary, a new grenade launcher is docked.

 Due to the above design differences, the reliability of hitting the target with the proposed portable grenade launcher system is significantly increased while reducing its overall dimensions and simplifying the design. YYY2 YYY4 YYY6 YYY8 YYY10

Claims (8)

 1. Wearable grenade launcher system containing two interconnected launch containers with sighting and firing devices and shots placed inside, the containers being placed so that their sighting devices are directed to one side and placed on opposite sides of the complex, each container being equipped with two with folding pistol-type handles, each shot consists of a grenade and a jet engine with a combustion chamber, and around the junction of the grenade and the jet engine in a container The free volume is formed, the grenade has a liquid or paste-like charge and is equipped with a device for twisting the charge when the grenade rotates and a device that prevents rebound when it hits an obstacle, and the jet engine is installed with the possibility of separation from the grenade and the container when fired, equipped with a gas shutter on the outer surface and made with throttle holes connecting the combustion chamber to the gas shutter and free volume around the junction of the grenade and the jet engine.  2. The complex according to claim 1, characterized in that the container connection elements are located in two spaced places along the length and are represented by pins with their fixing elements, for example, radial protrusions and a longitudinal symmetrical groove at the end of each pin installed in the holes of the eyes made two on the tops of the protrusions having the same shape and size and offset relative to the horizontal plane passing through the axis of symmetry of the container in one direction by the thickness of the eyelet, while on top of each protrusion pa at the base farthest from the eye axis of the container has a longitudinal groove under the eye response of the container, and projections are fixed on each container relative to its opposite side of the impact device.  3. The complex according to claim 1, characterized in that the gas shutter on the jet engine is made in the form of an annular lowering, and the throttle hole connecting it to the combustion chamber is located on one side at the location of the igniter of the powder charge of the jet engine, and another coaxial to a radial hole made in the wall of the container and connecting the gas shutter with an afterburner mounted on the side surface of the container from the outside against the firing device and containing an impact igniter th action and an additional propellant charge.  4. The complex according to claim 1, characterized in that the jet engine is equipped with a pressure regulator located in its nozzle block and made in the form of a perforated support with a membrane on which there is an elastic thermal insulation coating on the side of the powder charge, for example, a rubber layer, while the perforation of the support on the membrane side is provided with chamfers, and the membrane is made of ductile metal, such as copper.  5. The complex according to claim 1, characterized in that the grenade is made in the form of a thin-walled ampoule, the centering belts of which have a box section open to the charge of the grenade, and are lowered relative to the inner surface of the container, providing a profile gap between them for the passage of powder gases, at the same time, a glass with an ignition-explosive charge and a contact fuse is mounted on the axis of the ampoule.  6. The complex according to claim 5, characterized in that the device for twisting the grenade charge is made in the form of protrusions on the outer surface of the glass with an ignition-explosive charge and fuse and oblique, stabilizing the grenade in flight plates mounted on a hollow cylindrical skirt attached to the bottom of the grenade outside from the side of the jet engine, while in the wall of the skirt between the stabilizing plates and the bottom of the grenade there are bypass windows, and on the stabilizing plates are stamped, with the vertices to When the plates are folded in contact with the inner surface of the container.  7. The complex according to claim 5, characterized in that the device of the anti-recoil grenade from the obstacle is made in the form of a central rod with a thickening, mainly conical, protruding beyond the hollow ballistic tip of the grenade and the pressing mass, represented by a glass with an ignition-explosive charge, thin-walled a skirt with stabilizing plates and elements of their fastening to the bottom of the grenade.  8. The complex according to claim 1, characterized in that the firing device is placed on the container side of the container opposite to the sighting device and is represented by a V-shaped torsion spring mounted on the axis of the rear pistol grip and a striker located above the handle between the guiding cylindrical pin and the trigger sear, while on the hammer there is an annular groove with conical surfaces at the ends, between which the shoulder of the V-shaped spring is placed, covering the hammer in there are grooves, and two transverse grooves, the front walls of which interact with the trigger sear and provide, when the sear is in the groove closest to the annular groove, a combat cock, and in the distant safety cock, while the rear walls of the grooves are provided with horizontal protrusions for the sear groove .

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