RU2148232C1 - Disposable rocket launcher - Google Patents

Abstract

FIELD: hand arms. SUBSTANCE: rocket launcher has a launching container with drop covers, firing mechanism with an afterburner, rocket connected to a jet engine through a piston, sight with a fore sight, strip and slider. The afterburner is provided with a stepped bush, whose step of the larger diameter faces the firing mechanism and is pressed to it by a thread plug on the side of the container rear end face. The bush duct accommodates the primer cap and an additional powder charge. The thin-walled skirt of the jet engine and the launching container have slots that are open towards their rear end faces, and aligned with the lateral throttle orifice of the jet engine and radial orifice of the afterburner respectively. The piston is made in the form of a cup with an elliptic bottom and rectangular orifices in periphery, which accommodate the collet tabs; the cup is installed with its concave surface facing the jet engine. The fore sight is made in the form of a bar with a shift relative to its threaded base in radial direction by a value equal to the sum of the manufacturing tolerances for the sight components and their mating components of the container. The strip is box-shaped and has a longitudinal slot and diopter holes in the opposite wall. The slide is made of a flexible metal plate with a height not less than the distance between the three diopter holes of the strip, and provided with a lock. EFFECT: enhanced reliability and efficiency, reduced cost. 9 dwg

Description

 The invention relates to defense technology and can be used in the construction of grenade launchers, mainly disposable.

 The disposable hand grenade launchers have rather high and contradictory requirements: on the one hand, they must be cheap, easy to manufacture and operate, and on the other, reliable and efficient.

 In practice, this is implemented in a large group of intermediate variants of grenade launchers, in which complex and costly impact mechanisms and optical sights are mounted on parts of the grenade launcher barrel and form a reusable shotgun, to which the second part of the disposable barrel is attached for firing, containing a grenade and a jet engine.

 Examples of such grenade launchers can be a grenade launcher according to UK patent N1288732 C. F3A, F 42 B 9/12, publ. 09/13/72, and the 4-barrel hand grenade launcher XM-191 USA, described in the journal "Foreign Military Review" published. "Red Star", Moscow, 1975, N2, February, pp. 47-48, which are analogues of this invention.

The disadvantages of these grenade launchers include the following:
the complexity and cost of the design, including due to the presence of an optical sight, the advantages of which are negated by technological tolerances for the manufacture of elements of relative orientation and mechanical connection of the barrel parts, which lead to their distortion and impair accuracy and accuracy of fire;
difficult operation due to the need to connect the gun and shot before firing and to maintain the cleanliness and serviceability of their elements of mutual orientation and mechanical connection;
the need to preserve the gun and move with it after the expenditure of a portable ammunition of shots, which creates significant inconvenience;
the need to conduct special training of grenade launchers for the operation of grenade launchers and to have rocket launchers in the troops of the carriers, which does not allow the use of grenade launchers by any or all motorized gunners as additional weapons and thereby create fire superiority over the enemy.

 These disadvantages are largely eliminated in a disposable grenade launcher from the Wearable Grenade Launcher system of the Russian patent N2062428 dated June 20, 1996, F 41 F 3/045, F 42 B 5/05 (prototype of the present invention).

 This grenade launcher consists of a launch container with end caps that are dropped during firing, on which a mechanical sight is mounted, containing a front sight and a bar with an engine, and an impact mechanism with an afterburner in which an additional powder charge and an igniter capsule are placed and which is connected to the cavity by a radial hole launch container.

 A jet engine and a grenade are placed in the cavity of the launch container, connected to each other by a spreading grip fastened by thread with a grenade. The protrusions of the collet petals are installed in the annular groove of the jet engine, made around the throttle hole passing from the combustion chamber of the jet engine along its axis into the cavity of the launch container between the jet engine and the grenade, and is held in it by a piston ring, fitted with an interference fit on the collet.

 A throttle hole is made in the side wall of the jet engine, coaxial with the radial hole of the afterburner of the percussion mechanism.

 The jet engine is connected to the launch container by elastic plates, the ends of which pass through the slots in a thin-walled skirt attached to the jet engine from the side of its nozzle block, and enter the annular groove coaxial with the slots of the skirt and made on the inner surface of the launch container.

 In order to reduce the error of aiming, the mechanical sight of a grenade launcher, including for single use, should have a sufficiently high discreteness of installation of the engine on the bar and ensure high accuracy of its alignment with the barrel of the weapon.

 Alignment of the sight in the horizontal plane is carried out by moving the slider, for which he and the gun barrel have guiding and locking elements.

The disadvantages of the known disposable grenade launcher include low reliability and efficiency, high design complexity and cost caused by:
the instability of the additional powder charge of the afterburner due to the lack of a device for forcing the powder elements to hold an additional charge from carrying them out into the cavity of the launch container during combustion, which leads to the need to increase the mass of the additional powder charge and leads to a spread in the ignition intensity of the reactive powder charge engine, increased lateral disturbances on the launch container during firing and increased dispersion of the muzzle velocity of the grenade;
the lack of a device for orienting in the circumferential direction of the jet engine with a side throttle hole against the radial hole of the afterburner, which can lead to their rotation relative to each other during operation under the influence of vibration and shock loads and will cause a refusal to initiate the powder charge of the jet engine;
the lack of a device for forcibly holding the piston on the expanding collet, which can lead to the displacement of the piston along the collet to the grenade under the influence of shock loads during operation and detachment of the jet engine from the grenade, which will be accompanied by their collisions during firing and a change in the muzzle velocity of the grenade;
the lack of a device for the forced reliable movement of the piston along the collet to the grenade under the influence of powder gases during firing, which can lead to failure to separate them when fired, to reduce the muzzle velocity of the grenade and to refuse cocking its fuse due to a decrease in linear overload;
the large mass and rigidity of the plates fastening the jet engine to the launch container, since the reliability of such fastening when the plates are flat is determined only by their section, which leads to increased disturbances on the launch container during firing caused by the removal of their ends from the annular groove of the launch container and slots of a jet engine skirt;
the complexity of the design of the sight due to the presence of a large number of fairly complex and accurate parts, ensuring its alignment and fixing the engine on the bar;
low accuracy of sight alignment at all firing ranges due to tolerances on the manufacture of a large number of parts that affect it (bar and its grooves, slider and slot, retainer and its protrusion, etc.);
major errors in pointing the weapon at the target due to exposure to the slots of the grenade launcher’s engine and the sun’s sun, flashes of explosions and fires in the hemisphere from the side of the target.

 The objective of the present invention is to increase the reliability and effectiveness of grenade launchers while reducing their cost.

According to the invention, the task is achieved in that in a disposable grenade launcher containing a launch container with end caps discharged during firing; an impact mechanism with an afterburner having a radial hole extending into the cavity of the launch container, an additional powder charge and an igniter capsule; grenade; a jet engine, the combustion chamber of which is connected by an axial throttle hole to the cavity of the launch container between the jet engine and a grenade and a side throttle hole, with a radial hole of the afterburner; expanding collet and piston connecting the jet engine with a grenade; elastic plates, the ends of which are installed in the slots of a thin-walled skirt of a jet engine and an annular groove of the launch container coaxial with it, and a sight with a front sight, a bar and an engine covering the bar and having a latch for its position on the bar, interacting with the reciprocal grooves of the bar:
the afterburner is equipped with a sleeve with a stepped outer surface, installed with a large diameter step to the impact mechanism and a threaded plug pressed to it, screwed into the afterburner from the rear end of the launch container and having an end blind recess in which part of the step of the smaller diameter of the sleeve is recessed, while the igniter capsule and the additional powder charge are placed in the bushing channel, the bushing channel from the side of the threaded plug is blocked by a plug pressing the additional powder charge to the igniter capsule, in the wall of the sleeve part recessed in the end blind recess of the threaded plug, radial holes are made between the plug and the bottom of the blind end recess, and a radial clearance is formed between the sleeve and the cylindrical wall of the blind end recess smaller than the dimensions of the powder elements of the additional powder charge;
in the thin-walled skirt of the jet engine and in the launch container, grooves are made open to their rear ends, coaxial to the lateral throttle hole of the jet engine and the radial hole of the afterburner chamber, in which a key is mounted, held by the rear end cover of the launch container and containing side protrusions installed in the radial clearance between the launch container and the thin-walled skirt of the jet engine;
the elastic plates between the ends installed in the slots of the thin-walled skirt of the jet engine are U-shaped and installed with the elastic stop by the parts forming the U-shaped in the inner surface of the thin-walled skirt of the jet engine and the rear end cover of the launch container;
the piston is made of sheet metal in the form of a bowl with an elliptical bottom and rectangular holes along the periphery in which the petals of the expanding collet held by them are placed, while the bowl is mounted with a concave surface to the jet engine and at its end contains protrusions made at the same time between the rectangular holes and bent into an annular groove made on the jet engine behind the annular groove in which the tabs of the petals of the expanding collet are installed;
the front sight is made with a shift relative to its threaded base in the radial direction by an amount equal to the sum of technological tolerances for the manufacture of parts of the sight and the corresponding parts of the launch container, mainly by double consecutive bending in one plane, but in opposite directions by 90 ^{o of the} rod forming the front sight and its threaded base;
the bar is made of sheet metal rolled in a box-shaped cross section with a continuous slot along which it is mounted to the front sight, a number of diopter holes are made in the wall of the bar against the slot corresponding to the firing range, and a series of through grooves are made along its edge along the slot diopter holes, under the engine lock;
the engine is made of elastic sheet metal, and its latch is made on the side of the grooves in the plank in the form of a protrusion of a U-shaped integral with the engine and bent from the plank by an amount greater than the depth of its end entering the groove of the plank from the side of its slot, and the slider in front of the plank has a hole larger than the diopter hole of the plank, and the height of the slider along the plank is equal to or greater than the distance between any three adjacent diopter holes of the plank.

 The essence of the invention is illustrated in the drawing, where in FIG. 1 is a sectional perspective view of a disposable grenade launcher; FIG. 2, 3 - afterburner and orientation using a throttle dowel with a side throttle bore against the radial bore of the afterburner, FIG. 4 - the junction of the jet engine with the launch container using elastic plates, in FIG. 5 - the junction of the jet engine with a grenade using an expanding collet with a piston; in FIG. 6, 7 - front sight (side and top views, respectively), in FIG. 8 is a view of the bar of the sight with the engine from the side of the grenade launcher and in FIG. 9 - bar sight and the engine in cross section passing through the retainer of the engine.

 The disposable grenade launcher according to the invention consists (see Fig. 1) of a launch container 1, on which a percussion mechanism 2 with an afterburner 3 is fixed, and a sight, consisting of a front sight 4 and an aim bar 5. The ends of the launch container 1 are closed by the thin-walled end caps that are fired when fired lids 6 held by union nuts 7. Inside the launch container 1, a jet engine 8 and a grenade 9 are placed.

 The afterburner chamber (see Figs. 2 and 3) is closed by a threaded plug 10 from the rear end of the launch container 1, in which an end recess 11 is made from the bottom of the afterburner. A step sleeve 12 is installed inside the afterburner, which is installed with a large diameter step to the afterburner bottom the chamber and the threaded stopper pressed to it 10. Inside the sleeve 12, an igniter capsule 13 and an additional powder charge are placed 14. From the side of the threaded stopper 10, the channel of the sleeve 12 is closed by a plug 15, and between its lower diameter and the side wall the end recess 11 of the threaded plug 10 formed a radial clearance, the size of which is smaller than the dimensions of the powder elements of the additional powder charge 14.

 Radial holes 16 are made in the wall of the sleeve 12 in the cavity of the end recess 11 of the threaded plug 10 between its bottom and the plug 15.

 Afterburner 3 with a radial hole 17 is connected to the cavity of the launch container 1.

 The jet engine 8 (see Fig. 2) is equipped with a side throttle hole 18 coaxially to the radial hole 17 of the afterburner 3 and is forcedly held in this position by a key 19 installed in the coaxial grooves made in the rear end of the launch container 1 in the launch container and thin-walled skirt 20 connected by the nozzle block 21 to the jet engine. The key 19 (see Fig. 3) has lateral protrusions 22 mounted in the radial clearance between the launch container 1 and the thin-walled skirt 20 and is thereby prevented from falling out in the radial direction, in the longitudinal direction, the key 19 is held by the rear end cover 6 of the launch container 1.

 The jet engine 8 (see Fig. 4) is prevented from longitudinal movements in the launch container 1 by an elastic plate 23, the ends of which are passed through the slots 24 in the thin-walled skirt 20 and are installed in the annular groove 25 made in the launch container 1. An elastic plate 23 between it the ends placed in the slots 24 of the thin-walled skirt, made U-shaped and installed with elastic stop bent parts that form its U-shaped, in a thin-walled skirt 20 and the rear end cover 6 of the launch container 1.

 The jet engine 8 (see Fig. 5) is connected to a grenade 9 with a expanding collet, fastened with a thread with a grenade 9. The protrusions 27 of the collet petals 28 are mounted in an annular groove made on the housing of the jet engine 8 around the throttle hole 29 passing from its combustion chamber in cavity of the launch container between the jet engine and the grenade. The protrusions 27 of the petals 28 of the collet 26 are forcibly held in the annular groove of the jet engine 8 by a piston 30 made by stamping from sheet metal in the form of a bowl with an elliptical bottom. Rectangular holes 31 are made along the periphery of the bowl in its bottom, through which the petals 28 of the collet 26 are passed. The piston 30 is forcibly retained from longitudinal movements along the collet 26 by protrusions 32 made at its end between the rectangular holes 31 and bent into the annular groove 33 made on the jet the engine 8 behind the annular groove in which the protrusions 27 of the petals 28 of the collet 26 are installed.

 The front sight 4 of the grenade launcher sight (see FIGS. 6 and 7) is screwed into the protrusion 34, mounted on the launch container, and is a rod with a threaded base 35, the top of which is bent from the axis of the base 35 parallel to it by 36, equal to the sum of technological tolerances for the manufacture of the parts of the sight and the corresponding parts of the launch container, determining the deviation of the line of sight of the sight from the axis of the launch container in the horizontal plane.

 The sighting bar 5 (see Fig. 8, 9) is a bar 37, on which an engine 38 is mounted with the possibility of movement along it.

 The bar 37 is made by stamping from sheet metal and in cross section has a box shape with a slot 39 between its edges, which it is installed on the launch container and front sight 4. In the machine bar 37 against the slot 39 made a number of diopter holes 40, corresponding to the firing ranges of the grenade launcher disposable use, and along one of the edges of the strips from the side of the slot 39 is made a series of through grooves 41 corresponding to the diopter holes 40.

 The engine 38 is made by stamping from an elastic sheet metal, covering the bar 37 without overlapping the slot 39 in it and having a height along the bar greater than the distance between any three adjacent diopter holes. In the engine 38 from the side of the diopter holes 40 of the strap 37, a hole 42 is made, the size of which is significantly larger than the diameter of the diopter hole 40.

 The latch 43 of the engine 38 (see Fig. 9) is made U-shaped integrally with the engine on the side of the grooves 41 of the strap 37. The end of the U-shaped clamp 43 is installed in the groove 41 of the strap 37 to a depth 44 less than the amount 45 by which the lock bent from the bar 37.

 The work of a disposable grenade launcher is as follows.

 To make a shot, set the bar 5 of the sight vertically (see Fig. 1), press the latch 43 of the slider 38 (see Fig. 8), set the slider 38 against the diopter hole 40 corresponding to the firing range of the grenade launcher, release the latch 43 and its end it enters the corresponding through groove 41 of the bar 37, fixing the slider on the bar against the necessary diopter hole. Then, the grenade launcher is aimed at the target, projecting front sight 4 (see FIG. 1) through it through the diopter hole 40, and the percussion mechanism 2, which initiates the igniter 13 (see FIG. 2) of the afterburner 3, is triggered. the igniter capsule ignites the powder elements of the additional powder charge 14 and, together with the plug 15, moves it to the bottom of the end blind recess 11 of the screw plug 10 screwed into the afterburner 3 from the side of the rear end of the launch container, thereby opening the possibility of the release of powder gases from the can Ala bushings 12 into the cavity of the afterburner chamber 3 through the radial holes 16. From the afterburner, the powder gases through its radial hole 17 and the lateral throttle hole 18 of the jet engine 8 coaxial with it (see Fig. 1) enter the combustion chamber of the latter and ignite its powder charge .

The powder gases from the combustion of the powder charge of a jet engine flow out of its combustion chamber simultaneously through the holes in the nozzle block 21 (see Fig. 2) back, and through the throttle openings 29 (see Fig. 5) forward - into the cavity of the launch container between the grenade 9 and jet engine 8. In this case:
powder gases flowing backward (see Figs. 2 and 4) deform the rear end cover 6, snap it out of the seal between the start container 1 and the union nut 7, at the same time they bend the elastic plate 23 in the middle part, which it rested on the rear end cover 6, and that, leaning in turn with the bent parts on the thin-walled skirt 20, without bumps and jerks transmitted to the launch container, comes out with its ends from the annular groove 25 of the launch container and the slots 24 of the thin-walled skirt 20 and together with the rear end cover you throws powder gases back;
powder gases flowing forward (see Fig. 5), almost completely restore their pressure on the concave surface of the elliptical bottom of the bowl 30 with a large force arising from this, unbend its end protrusions 32, removing them from the annular groove 33 of the jet engine 8, and move bowl 30 to the grenade 9, releasing the petals 28 of the expanding collet 26, which diverge under the action of their own elastic forces and pressure of powder gases and withdraw their protrusions 27 from the annular groove of the jet engine 8.

 After detaching the jet engine 8 (see Fig. 1) from the launch container 1 and grenade 9, the latter accelerates under the influence of the pressure of the powder gases along the length of the launch container, knocks out its front end cover and flies to the target, and the jet engine under the influence of the difference in forces from pressure on it, the powder gases in the launch container and its own reactive thrust created by the powder gases flowing back from its combustion chamber, make several reciprocating movements along the launch container and depending and from the grenade temperature remains in the starting container or falls out of it forward or backward. In this case, the key 22 (see. Fig. 2 and 3) does not interfere with this movement of the jet engine in the launch container, because in the longitudinal direction, it does not connect them and after resetting the rear end cover 6, the pressure of the powder gases is thrown back.

 Alignment sight grenade launcher is made in the following order.

By screwing the front sight 4 (see Figs. 6 and 7) with the base 35 into the threaded hole of the protrusion 34, they are projected through the diopter hole 40 (see Fig. 8), corresponding to the effective range of the grenade launcher, in the center of the square or circle of the target. In this case, the front sight can be located in the left or right sector, limited by an angle of 60 ^o , and the maximum error of sight alignment at a distance of 20 m when the axes of the diopter holes deviate from the nominal location in the horizontal and vertical directions ± 0.1 mm (technological tolerance for the manufacture of diopter holes ), the thread pitch of the front of the fly, equal to 1 mm, and the base of the sight (distance from the front of the fly to the bar), equal to 300 mm, will be: in the horizontal plane ± 13 mm and in the vertical plane ± 19 mm. This is significantly less than that of regular grenade launchers (see the manual "RPG-2 Hand-held Anti-Tank Grenade Launcher", published by DOSAAF, Moscow, 1969).

 Due to the above design differences in the disposable grenade launcher proposed according to this invention, a reduction in the complexity and cost of its manufacture is achieved while improving reliability and efficiency (firing accuracy) in comparison with the analogue and prototype.

Claims (1)

A disposable grenade launcher containing a launch container with end caps that are dropped when fired; an impact mechanism with an afterburner having a radial hole extending into the cavity of the launch container, an additional powder charge and an igniter capsule; grenade; a jet engine, the combustion chamber of which is connected by an axial throttle hole to the cavity of the launch container between the jet engine and a grenade and a side throttle hole, with a radial hole of the afterburner; expanding collet and piston connecting the jet engine with a grenade; elastic plates, the ends of which are installed in the slots of a thin-walled skirt of a jet engine and an annular groove of the launch container coaxial with it, and a sight with a front sight, a bar and an engine covering the bar and having a latch for its position on the bar, interacting with the reciprocal grooves of the bar, characterized in that the afterburner is equipped with a sleeve with a stepped outer surface installed by a large diameter step to the percussion mechanism and a threaded plug pressed to it, screwed into the afterburner from the rear side end of the launch container and having an end blind recess in which a part of the step of a smaller diameter of the sleeve is recessed, while the igniter capsule and additional powder charge are placed in the channel of the sleeve, which is closed by a plug on the side of the threaded plug, which compresses the additional powder charge to the igniter capsule, in the wall of the part of the sleeve recessed in the blind end recess of the threaded plug, radial holes are made between the plug and the bottom of the blind end recess, and a torus between the sleeve and the cylindrical wall a radial clearance is formed in the central recess, smaller than the dimensions of the powder elements of the additional powder charge; in the thin-walled skirt of the jet engine and in the launch container, grooves are made open to their rear ends, coaxial to the lateral throttle hole of the jet engine and the radial hole of the afterburner chamber, in which a key is mounted, held by the rear end cover of the launch container and containing side protrusions installed in the radial clearance between the launch container and the thin-walled skirt of the jet engine; elastic plates are made with double sequential bending in one plane, but in opposite directions 90 ^° from the axis of the plate and are installed with elastic emphasis by parts forming a U-shaped shape in the inner surface of the thin-walled skirt of the jet engine and the rear end cover of the launch container; the piston is made of sheet metal in the form of a bowl with an elliptical bottom and rectangular holes along the periphery in which the held or petals of the expanding collet are placed, the bowl being installed with a concave surface to the jet engine and at its end contains protrusions made at the same time between the rectangular holes and bent into an annular groove made on the jet engine behind the annular groove in which the tabs of the petals of the expanding collet are installed; the front sight is made with a shift relative to its threaded base in the radial direction by an amount equal to the sum of technological tolerances for the manufacture of parts of the sight and the corresponding parts of the launch container, mainly by double consecutive bending in one plane, but in opposite directions by 90 ^{° of the} rod forming the front sight and its threaded base; the bar is made of sheet metal rolled in a box-shaped cross section with a continuous slot along it facing the front sight; in the wall of the bar against the slot there are a number of diopter holes corresponding to the firing range, and along its edge along the slot there are a number of through grooves corresponding to the diopter holes, under the engine lock; the engine is made of elastic sheet metal, and its latch is made on the side of the grooves in the plank in the form of a protrusion of a U-shaped integral with the engine and bent from the plank by an amount greater than the depth of entry of its end into the groove of the plank from the side of its slot, and a hole is made in the engine in front of the bar larger than the diopter hole of the bar, and the height of the engine along the bar is made equal to or greater than the distance between any three adjacent diopter holes of the bar.

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