RU2342623C1 - Jet multimission grenade - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: grenade includes the jet engine and a fighting part which contains a forward cumulative head part supplied with a detonator of instant action and equipped with high-explosive or thermobaric structure basic head part between which the safety plug connected to a cover placed before the basic head part with a thin bottom is established. Lateral walls of the cover are executed with weakening groove, and the safety plug contains a bottom indestructible at explosion of a cumulative head part and destroyed lateral walls. The basic head part contains a detonator executed with possibility of definitively raising from overloads, arising at explosion of a forward cumulative head part and with possibility of operation depending on barrier type.

EFFECT: increase of efficiency of destruction of various types of barriers and after-penetration effect.

5 cl, 15 dwg

Description

The invention relates to the field of weapons, and more particularly to means of close combat - multiple rocket launchers designed to destroy manpower located behind various obstacles.

Known multi-purpose grenades, as a rule, in their design have combined warheads of the tandem type of two-stroke action, the front stage of which is cumulative, and the rear one is fragmentation. The main difficulties facing the developers of such ammunition are:

- providing the front cumulative warhead with a diameter of a hole in obstacles of different strength and thickness (armor, brick, reinforced concrete wall, wood-earth roof, etc.), sufficient for penetration of a fragmentation warhead beyond the obstacle;

- protection of an explosive substance (explosive) fragmentation warhead from detonation during the explosion of the front cumulative warhead, especially if they are structurally located in a single building;

- ensuring penetration of the fragmentation warhead into the barrier space, including at angles of contact between the munition and the obstacle from 0 ° to 75 ° from the normal to the obstacle (generally accepted requirement of the tactical and technical specifications for the development of such ammunition);

- providing the necessary time delay for the fuse of the fragmentation warhead relative to the explosion of the front cumulative warhead with the smallest possible fuse dimensions, because it is inside the fragmentation warhead.

The indicated tasks are solved, for example, in the Bunkerfaust grenade (Germany, Jane handbook, 2003-2004, p. 167) by using a relatively large caliber (110 mm) of the front cumulative warhead with a low funnel and small caliber ( 47 mm) of a fragmentation warhead, a separation between the cumulative and fragmentation warheads and the use of autonomous fuses for each warhead. Moreover, “Bunkerfaust” has a relatively low efficiency, because skid fragment fragmentation is provided only for rather thin obstacles (armor ≤17 mm thick, brick wall ≤250 mm thick).

Known penetrating grenade with a single fuse, selected as a prototype (patent No. 5686692 from 11.11.1997, USA, 105/352).

The penetrating grenade contains a rocket engine and a warhead, which includes the front main warhead, a secondary anti-personnel fragmentation grenade and an explosive system located in a single building. The fuse system is a primary fuse and a secondary fuse, working with a delay, interconnected by a detonating cord. The secondary fuse has a timer and a shift detonator. When the warhead meets an obstacle, a primary fuse fires, which initiates a detonating cord that undermines the front main warhead and initiates the activation of the delay timer circuit and the shift detonator. In front of the fragmentation grenade is a lid consisting of several layers of plexiglass or plastic with aluminum, which protects the fragmentation grenade from exploding the main warhead. Alternating layers of plexiglass and aluminum absorb and disperse the energy of the shock waves from the explosion of the main warhead. The shear detonator explodes instantly from the detonating cord, causing the slider to move along the guides in the secondary fuse until the detonator is aligned with the timer delay circuit. Before the shift detonator is activated, the engine is in an offset position relative to the timer delay circuit. This serves as a stage of protection, eliminating the explosion of a fragmentation grenade before the main warhead is triggered. The timer delay circuit provides a delayed initiation of a fragmentation grenade for a predetermined time necessary for it to pass through a hole in an obstacle from an explosion of the main warhead. At the end of the operation of the timer delay circuit, the detonator of the secondary fuse is pushed through the wall of the secondary fuse into the explosive fragmentation grenade, providing it undermines and defeats the manpower beyond the obstacle.

The above single-firing piercing grenade has disadvantages. The main disadvantage is that, like Bunkerfaust, it will have low efficiency, because it is impossible to bring a fragmentation grenade behind a powerful barrier, having dimensions commensurate with the caliber of the main warhead (as indicated in the patent). So, if when meeting a grenade with a target, the main warhead pierces a hole in the obstacle whose diameter is smaller than the dimensions of the fragmentation grenade, then the fragmentation grenade will reflect upon it and will not fall into the obstacle space. Such a result is most likely with thick or hard obstacles, as well as with small angles of approach of the grenade to the target. In addition, due to the use of a detonating cord twisted into a spiral, as well as the high complexity of the secondary fuse due to the use of a movable shear detonator in it, the grenade will not be technological, labor-intensive and difficult to manufacture, especially serial, will have low reliability and high cost .

The task of the claimed invention is to increase the effectiveness of the multi-purpose grenade against barriers that are heterogeneous in strength, stiffness and thickness, as well as to increase the restraining effect.

The technical result consists in increasing the destruction of the barrier and increasing the skidding over the barrier of detonation products, shock waves and fragments, as well as increasing the restraining effect when the barriers are heterogeneous in strength, stiffness and thickness.

The technical result is achieved by the fact that a multi-purpose rocket-propelled grenade includes a jet engine (RD) and a warhead, which contains a front shaped-charge warhead equipped with an instant-action fuse and a main warhead equipped with a high-explosive or thermobaric composition, between which a safety sleeve is connected, connected to a thin-bottom lid placed in front of the main head. The side walls of the lid are made with a weakening groove, and the safety sleeve contains a bottom that is not destroyed during the explosion of the cumulative head part and destructible side walls, while the main head part contains the fuse, which is finally cocked from overloads arising from the explosion of the front cumulative head part, and the actuation in depending on the type of obstruction.

The thickness of the thin bottom of the lid can be no more than 0.12d ₁ , where d ₁ is the diameter of the bottom of the lid, and the thickness of the side wall is not more than 0.06d ₁ at the location of the groove, where d ₁ is the diameter of the bottom, provided that the strength of the material cover does not exceed the strength of the material of the body of the main head part.

The safety sleeve, containing the bottom that is not destroyed during the explosion of the cumulative head part, and the side walls that are destroyed, ensures the integrity of the OHC during the explosion of the front head part (HRP) and the prevention of premature detonation of the explosive material of the OHC.

The thickness of the bottom of the safety sleeve may be at least 0.4 d ₂ , and the thickness of its side walls may not exceed 0.05 d ₂ , where d ₂ is the diameter of the bottom, provided that the strength of the material of the sleeve does not exceed the strength of the material of the body of the main head.

A cover with a thin bottom and side walls, made with an attenuating groove, located in front of the main head part, ensures maximum drift of detonation products and unhindered passage of the shock wave beyond the “hard” barrier, since the thin bottom is easily destroyed by an OGF explosion, and the side walls are destroyed by an explosion PPP.

The specific thicknesses of the bottoms and walls of the cover of the main head part and the safety sleeve are selected experimentally depending on the power of the front cumulative head part and the safety-actuating mechanism of its fuse.

The use of a fuse, the final cocking of which occurs due to overloads arising from the explosion of the PPP, and the operation depending on the type of obstacle, provides a detonation of the VHF depending on the type of obstacle both outside and inside the obstacle.

As such a fuse for the main warhead, an impact fuse may be used, including an overload mechanism, a firing mechanism, and a pyrotechnic time delay circuit.

If the obstacle is “hard” - a thick armor plate, a thick brick or reinforced concrete wall, in which the PHC makes a hole smaller than the diameter of the OGC and RD, then the fuse mechanism of the fuse is triggered when the OGC hits the obstacle (outside or inside the barrier). To ensure maximum drift of the detonation products and unhindered passage of the shock wave beyond the “hard” barrier, the lid covering the front part of the VHF has a thin bottom that easily collapses during the explosion of the VHF and collapses during the explosion of the VHF side wall. The integrity of the VHF during the explosion of the VHF and the elimination of premature detonation of the explosive substance of the VHF provides a safety sleeve installed between the VHF and the VHF with a thick non-destructible during the explosion of the VHF bottom, but collapsing side walls. The wall of the cover that collapses during the explosion of the PHC together with the collapsing wall of the sleeve provides a decrease in the maximum value of the force due to the overload acting on the VHF from the explosion of the PHC, while stretching it along the time of action.

If the barrier is “soft” - car sheathing, plank or adobe wall, thin brick or reinforced concrete wall, glass, etc., that is, obstacles in which the PHC makes a hole sufficient for the VHF and RD to penetrate through the barrier, then the the fuse mechanism, due to the pyrotechnic time delay circuit, is triggered after a specified time, providing undermining of the VLF inside objects limited by the indicated barriers.

The invention is illustrated by drawings, depicting:

figure 1 is a General view of a multiple rocket launcher;

figure 2 shows the cover having a collapsing side wall that collapses during the explosion of the PHC and does not collapse during the explosion of the PHC;

figure 3 shows the safety sleeve having collapsing during the explosion of the PPP side wall and a thick non-destructive bottom;

figure 4 shows a grenade at the stage of meeting with an obstacle;

figure 5 shows the stage of operation of the HRP on a “rigid” powerful barrier (armor plate), while showing the hole punched in the barrier, the cumulative stream 14 and the propagating explosion products and shock waves in front of and behind the barrier, as well as fragments 15 of the walls of the VHF cover and the safety bushings and bottom 16 of the safety sleeve 9; at this time, the process of completing the firing of the 7 OHF fuses begins;

figure 6 shows the stage of the meeting of the OGF with an obstacle, by this time the fuse of the OGCH is finally cocked;

7 shows the stage of operation of the OGF, while showing the propagation of explosion products and shock waves in front of and behind the barrier;

Figs. 8, 9 show the stage of operation of the PHC on a "rigid" thick barrier (brick or reinforced concrete wall), while typical variations of the holes in the walls are shown (depending on the thickness of the walls), the propagation of explosion products and shock waves in front of and behind the barrier, a cumulative stream 14, fragments 15 of the walls of the cover of the OGF and the safety sleeve, the bottom 16 of the safety sleeve and fragments of the wall 17;

figure 10, 11 shows the stage of the meeting of the OGF with a "rigid" thick barrier (brick wall) inside it;

on Fig depicts the stage of operation of the OGF inside a brick wall, its destruction with the formation of a gap and the spread of explosion products, shock waves and fragments of the barrier 17 in front of and behind the barrier;

on Fig depicts the stage of operation of the PPP on a “soft” barrier (car skin, plank or thin brick wall, etc.), while the cumulative stream 14, the hole in the barrier, the propagation of explosion products and shock waves in front of and behind the barrier are shown , fragments 15 of the walls of the cover of the OGF and the safety sleeve, the bottom 16 of the safety sleeve and fragments of the wall 17;

on Fig depicts the stage of the passage of the OGF with the taxiway behind the "soft" barrier, while the OGF fuse cocked and there is a process of slowing down its operation;

on Fig depicts the stage of the explosion of the OGF behind the "soft" barrier after a predetermined time for the deceleration of the fuse of the OGC.

Multipurpose rocket launcher contains warhead 1 and rocket engine 2. Warhead 1 has a front cumulative warhead 3 and the main warhead 4, equipped with a high-explosive or thermobaric composition. The front head part 3 has a piezoelectric instant fuse, consisting of a piezoelectric generator 5 and a safety-actuating mechanism 6.

The main head part has an impact fuse 7, including a mechanism for overloading from overloads, a firing mechanism and a pyrotechnic time delay circuit located in the bottom part, and a cover 8 in front. A safety sleeve 9 is located between the front cumulative head part and the main head part.

The cover 8 has a side wall 10 that collapses during the explosion of the PHC and does not collapse during the explosion of the PHC. The thin bottom 11 is comparable in thickness to the wall of the VCP.

The safety sleeve 9 has a collapsing side wall 12 that collapses during the explosion of the PPP and a thick non-destructive bottom 13.

The action of multiple rocket grenades is as follows.

When the starting jet engine 2 is activated from the overloads acting in this case, the safety-actuating mechanism 6 of the ПГЧ 3 is cocked and the first stage of protection of the shock fuse 7 of the ОГЧ 4 is removed. When the grenade meets, the piezoelectric generator 5 is loaded, generating electric current and transmitting it to the safety-executive mechanism 6, which undermines the cumulative PPP penetrating the barrier. The final cocking of the shock fuse 7 occurs due to overloads caused by the explosion of the PGP, the tip of the firing mechanism is installed opposite the detonator capsule, and the pyrotechnic time delay circuit is activated, as well as from the impact of the explosion products and destroyed elements of the safety-executive mechanism 6 and its attachment point, destruction the walls 12 of the safety sleeve 9 and the walls 10 of the cover 8 VHF. OGCH at the same time remains intact.

If the barrier is “hard” and is a thick armor, then the PHP punches a hole in it, insufficient for the VHF to penetrate from the taxiway into the after-space. Then, the OGC hits an obstacle in the region of the opening formed by the OGP, an impact fuse 7 detonates the OGC, and the detonation products and shock waves from the explosion of the OGG through the opening made by the OGP penetrate into the afterglow.

If the “rigid” barrier is a thick brick or concrete wall, then the PPP breaks a hole in it with an entrance cover. The OGF enters the cavity and explodes inside the wall, causing significant damage to the wall (breaches), while the products of the OGH explosion, shock waves and wall elements defeat the living force behind the obstacle.

If the barrier is “soft” - car skin, glass, plank or thin brick wall, i.e. barriers in which the PHC makes a hole sufficient for the VHF to pass through the taxiway, then the fuse 7 is triggered by the pyrotechnic time delay circuit after a predetermined time, undermining the TGM in the after-space, with the most effective defeat of the manpower behind the obstacle.

Claims (5)

1. A multi-purpose reactive grenade, including a jet engine and a warhead, which contains a front shaped-charge head equipped with an instant-action fuse and a main warhead equipped with a high-explosive or thermobaric composition, between which a safety sleeve is installed connected to a thin-bottomed lid in front of the main head , the side walls of the lid are made with a weakening groove, and the safety sleeve contains an indestructible cumulative head ti breakable bottom and side walls, wherein the main head portion comprises a fuse configured to final charging overload occurring in the explosion front cumulative head portion and to actuate depending on the type of obstacles. 2. Grenade according to claim 1, characterized in that the main warhead contains an impact fuse, including a mechanism for additional loading from overloads, a firing mechanism and a pyrotechnic time delay circuit. 3. Grenade according to claim 1 or 2, characterized in that the thickness of the thin bottom of the lid does not exceed 0.12 d ₁ , and the thickness of the side wall of the lid at the location of the groove does not exceed 0.06 d ₁ , where d ₁ is the diameter of the bottom of the lid while the strength of the material of the cover does not exceed the strength of the material of the body of the main head part. 4. The grenade according to claim 1 or 2, characterized in that the thickness of the bottom of the safety sleeve is not less than 0.4 d ₂ , and the thickness of its side walls does not exceed 0.05 d ₂ , where d ₂ is the diameter of the bottom of the sleeve, the strength of the material of the sleeve does not exceed the strength of the material of the body of the main head part. 5. Grenade according to claim 3, characterized in that the thickness of the bottom of the safety sleeve is not less than 0.4 d ₂ , and the thickness of its side walls does not exceed 0.05 d ₂ , where d ₂ is the diameter of the bottom of the sleeve, while the strength of the material bushings does not exceed the strength of the material of the body of the main head part.

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