RU22817U1 - SHOPPING Grenade Launcher for Grenades with a Powder Throwing Charge - Google Patents

Description

SUBWAY Grenade Launcher For Grenade With Powder Throwing Charge

The utility model relates to weapons technology and can be used in small arms.

The closest in technical essence to the claimed prototype is an under-barrel grenade launcher for firing fans with a propellant propellant charge GP-25 (see the Technical Description for the GP-25 6T15TO under-barrel grenade launcher operating instructions from 1978, supplied with a GP-25 grenade launcher. 1, 56, 57, 68) comprising a body with a trigger mechanism, a barrel with an arm and a breech with a cylindrical internal cavity whose diameter is equal to the diameter of the grenade's shank, and the depth exceeds the length of the grenade's shank.

The well-known grenade launcher mounted on the machine, allows for targeted firing of fragmentation grenades with a powder charge.

A disadvantage of the known grenade launcher is the low range of aimed firing caused by the insufficient initial speed of the fan because it does not provide complete combustion of the powder gases of the charge of the fan.

In addition, since the barrel-mounted fan-gun is attached to the barrel of the submachine gun gear for the protrusion of the gas chamber, then the whole recoil force of the fan-gun when fired is transferred to the gas chamber of the machine, and due to the fact that when attaching the fan-gun to the machine it is impossible to avoid the existence of gaps in the mount, then the gas the camera experiences significant shock loads after sampling these gaps at the time the fanatomt recoils. The higher the fan speed of the fan at the moment of sampling the gaps, the greater the shock atus on the gas chamber, leading to premature destruction of the machine

The disadvantages also include the presence of a large number of misfires.

The objective of the utility model is to increase the range of targeted shooting.

The technical result is to increase the initial flight speed of the fans.

trigger mechanism, the barrel with the bracket and the breech, having an internal cavity along the diameter of the shank of the grenade, the internal cavity of the breech is made stepwise with rounded internal corners of the bottom of the cavity.

Moreover,

- the rounded inner corners of the bottom of the cavity are made radial and begin directly from the edge of the step,

- the stage of the inner cavity is made radial,

- the stage of the internal cavity is made with the possibility of interaction with the shank of the fans

The utility model is illustrated by means of the drawings, where in FIG. 1 shows a device of a grenade launcher attached to a machine with a grenade installed, in FIG. 2 - separately breech of a grenade launcher, in FIG. 3 is a rear view of a fan.

An under-barrel grenade launcher for grenades with a propellant propellant charge includes a housing 1 (Fig. 1) with a trigger mechanism having, among other things, a trigger 2 and a hammer 3, a barrel 4 with an arm 5, and a breech 6 (Fng. 2), having stepped inner cavity 7, with a step 8 n with rounded inner corners 9 of the bottom 10 of the cavity 7.

The grenade launcher is installed using the bracket 5 on the barrel 11 of the machine by engaging the protrusion 12 of the gas chamber 13 of the machine and is charged by the fan 14 (Fng. 3), which has a shank 15 with a powder propellant charge, on the back wall of which 16 there is a cap 17 n holes 18 emission of powder gases. The latch 19 provides a fixation of the position of the grenade 14 in the stop position by the rear wall 16 of the shank 15 in the plane of the step 8.

Stage 8 is made radial i.e. in the form of a continuous cylindrical cavity reduction with a flat transverse thrust pad.

The under-barrel fan gun works as follows.

Before firing shots, an under-barrel grenade launcher is mounted on the barrel 11 of the machine using the bracket 5. In this case, the fuse (not shown) is moved to a position that allows firing of a grenade launcher

To load the fanatom into the barrel from the muzzle, place the fan 14 introducing ev until the rear wall 16 interacts stubbornly into a flat surface

the steps 8 of the cavity 7 of the breech 5. In this position, the grenade is fixed using the lock 19.

When the trigger 2 is acted upon, the trigger mechanism is triggered, the hammer 3 breaks the capsule 17, which leads to ignition of the propellant propellant charge located in the shank 15.

The combustion products are ejected by jets through the openings 18 in the rear section of the shank 15 of the fan 14 into the cavity 7 of the breech 6 (combustion chamber). In this case, the presence of a step 8, which abuts against the rear wall of the shank 15 of the grenade and its edge fits directly to the edge of the hole 18 for ejecting gases, as well as the presence of a radial rounding of the internal corners 9 of the bottom 10, which starts directly from the edge of the step, provide a forced flow curvature ejected from the hole 18 gases (combustion products of the powder charge) n intensive mixing of the ejected streams.

Such mixing increases the efficiency of the combustion of the propellant propellant charge by ensuring that unburned particles of gunpowder burn out in the combustion chamber, unlike the prototype, where up to 30% of unburned propellant powder can be thrown from the barrel

Improving the efficiency of the combustion of gunpowder leads to an increase in gas pressure in the combustion chamber, which results in an increase in the initial speed of half a fan. Fans' faster flight speeds increase their aiming range.

In addition, the presence of a step in the breech cavity, against which the back wall of the charged fan abuts, provides a decrease in the surface area of the breech combustion chamber experiencing gas pressure of the combustible powder charge in the longitudinal direction of the shot at the initial moment of the shot, i.e. before the fans start moving.

Such a decrease in area leads to a decrease in the force acting on the fanatom in the opposite direction at the initial moment of the shot, and, therefore, to a decrease in the speed of the fanatom relative to the barrel of the machine within the bracket mounting clearances.

Lower than the prototype speed of the grenade launcher provides a softer attachment of the grenade launcher to the fastening elements located on the barrel of the machine after selecting the bracket mounting clearances

In currently existing machines, such a fastening element is the protrusion of the gas chamber, which experiences all the shock effects of the grenade launcher attachment with each shot.

Reducing the speed of the grenade launcher during recoil and softly attaching it to the machine reduces the load on the gas chamber during the recoil from the grenade launcher, reduces the displacement of the gas chamber and reduces the destruction of the machine

When loading the proposed grenade launcher, the grenade is inserted until it stops with the back wall of the shank of the grenade into the plane of the step of the breech cavity and is fixed in this position, while in the prototype the fan is inserted all the way into the edges of the breech against the stop. The capsules 17 for detonating the propellant propellant charge are pressed into the rear wall of the grenade shank. Given that the movement of the striker 3 is limited (about 1.5 mm), and the length of the section optimal for detonating the capsule is even shorter, a decrease in the spread in the capsule position of a fan of a charged fanatom relative to the position of the striker is important. The larger this scatter caused by manufacturing difficulties, the higher the probability of misfire due to the capsule not undermining (which turned out to be further than the optimal section of the striker movement) or the capsule being unintentionally detonated during loading (if the capsule turned out to be excessively protruding and was hit by a striker during loading).

In the prototype, the spread in the position of the capsule is determined by the sum of the errors of pressing the capsule and the manufacture of the shank, while in the proposed grenade launcher, the named spread is limited only by the pressure of pressing the capsule.

Reducing the dispersion of the position of the capsule relative to the striker in a charged fan-gun increases the operational reliability of the proposed fan-gun

Thus, the proposed underbarrel fanombt provides a higher impact range due to more efficient burning of the powder charge and increase the initial fan speed compared to the prototype.

The proposed grenade launcher also provides increased survivability of the machine with the existing system for attaching an underbarrel atomic era era by reducing the impact of the destructive force of the shock connection of the grenade launcher

In addition, the proposed grenade launcher has higher operational reliability by reducing the likelihood of misfires and involuntary detonation of the powder charge

1. A grenade launcher for fans with a powder propellant charge, including a body with a trigger mechanism, a barrel with an arm and a breech block having an internal cavity along the diameter of the grenade shaft, characterized in that the internal breech cavity is made stepwise with rounded internal corners of the cavity bottom.

2. A grenade launcher for fans with a propellant propellant charge according to claim 1, characterized in that the rounding of the internal corners of the cavity bottom is made radial and begins directly from the edge of the stage.

3. A grenade launcher for fans with a powder propellant charge according to any one of paragraphs 1 or 2, characterized in that the step of the internal cavity is made radial.

4. Subbarrel fan-thrower for fans with a powder propellant charge according to any one of paragraphs 1, 2, or 3, characterized in that the stage of the internal cavity is made with the possibility of interaction with the shank of the fan.

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Claims (4)

1. A grenade launcher for grenades with a propellant propellant charge, including a body with a trigger mechanism, a barrel with an arm and a breech, having an internal cavity along the diameter of the grenade shaft, characterized in that the internal breech cavity is made stepwise with rounded internal corners of the bottom of the cavity.  2. The underbarrel grenade launcher for grenades with a propellant propellant charge according to claim 1, characterized in that the rounding of the internal corners of the bottom of the cavity is made radial and begins directly from the edge of the stage.  3. Underbarrel grenade launcher for grenades with a threshold propelling charge according to any one of claim 1 or 2, characterized in that the stage of the internal cavity is made radial. 4. Grenade launcher for grenades with a threshold propellant charge according to any one of paragraphs. 1, 2 or 3, characterized in that the stage of the internal cavity is made with the possibility of interaction with the tail of the grenade.